modelling and calculus - university of sydneymodelling and calculus by collin phillips this material...
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Modelling and Calculus
By Collin Phillips
This material has been developed as a joint project between the Mathematics Learning CentreMLC and the Learning Centre LC at the University of Sydney. With literary and structuralcontributions from Dr Janet Jones and Ms Helen Drury of the LC.Thanks for the many useful suggestions and corrections by Dr Sue Gordon and Ms JackieNicholas of the MLC and, Mr George Papadopoulos and Prof. Leon Poladian of the Schoolof Mathematics and Statistics. Thanks also for the feedback and proofreading of the manystudents of the MLC including Dr Rukshana Yates and Ms Vanessa Kung.This material was developed with the aid of a Teaching Improvement and Equipment SchemeTIES Grant at the University of Sydney in 2010.
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Contents
1 Modelling and Calculus 1 MAC 1The interpretation and translation of natural and real world problems that are describedin words into a specification and description of the modelling problem in the language ofmathematics 4
1.1 Rates of Change and Derivatives . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
1.1.1 Identifying The Di!erence Between a Quantity and the Rate of Change of That Quantity 4
1.1.2 Exercises . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
1.2 What is a Di!erential Equation? . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
1.2.1 Description of a Di!erential Equation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
1.2.2 Constant Rate of Change . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
1.2.3 Exercises . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
1.3 Proportionality . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
1.3.1 Description of Proportional Quantities . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
1.3.2 Exercises . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
1.3.3 Constants of Proportionality . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
1.3.4 Exercises . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
2 Modelling and Calculus 2 MAC 2Understanding the concepts and ideas of di!erential equations and their solutions in termsof written word descriptions of the di!erential equations and the concepts of solving adi!erential equation. 11
2.1 Di!erential Equations as Questions: Various Variables . . . . . . . . . . . . . . . . . . . . . . . . 11
2.1.1 Solution Function and Independent Variable . . . . . . . . . . . . . . . . . . . . . . . . . . 11
2.1.2 Independent Variables and Dependent Variables . . . . . . . . . . . . . . . . . . . . . . . 11
2.1.3 Alternative Notations for Di!erential Equations . . . . . . . . . . . . . . . . . . . . . . . . 12
2.1.4 Exercises . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
2.2 Di!erential Equations as Questions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
2.2.1 Di!erential Equations of the Formdy
dx= f(x) as Questions . . . . . . . . . . . . . . . . . 14
2.2.2 Exercises . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
2.2.3 Di!erential Equations of the Formdy
dx= g(y) as Questions . . . . . . . . . . . . . . . . . 16
2.2.4 Di!erential Equations of the Formdy
dx= f(x)g(y) as Questions . . . . . . . . . . . . . . . 17
2.2.5 Exercises . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
2.3 Particular Solutions and General Solutions or Di!erentiating in Reverse . . . . . . . . . . . . . . 20
2.3.1 The di!erence between General Solutions and a Particular Solution . . . . . . . . . . . . 20
2.3.2 Exercises . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
2.3.3 Particular Solutions and General Solutions in General . . . . . . . . . . . . . . . . . . . . 22
2.3.4 Exercises . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
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3 Modelling and Calculus 3 MAC 3Solving some di!erential equations by using the concepts and interpretations of a di!eren-tial equation to find a solution or an answer posed by the di!erential equation. 25
3.1 Solving Di!erential Equations of the Formdy
dx= f(x) Using Di!erentiation in Reverse . . . . . . 25
3.1.1 Exercises . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
3.2 Di!erentiation Tables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
3.3 Solving Di!erential Equations of the Formdy
dx= f(x) Using Integration . . . . . . . . . . . . . . 32
3.3.1 Exercises . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
3.4 Checking Your Solution . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
3.4.1 Exercises . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36
3.5 Integration Tables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
3.6 Solving Di!erential Equations of the Formdy
dx= f(y) . . . . . . . . . . . . . . . . . . . . . . . . 39
3.6.1 Di!erential Equation of the Formdy
dx= y . . . . . . . . . . . . . . . . . . . . . . . . . . . 39
3.6.2 Exercises . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40
3.6.3 Di!erential Equation of the Formdy
dx= ky . . . . . . . . . . . . . . . . . . . . . . . . . . 41
3.6.4 Exercises . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42
3.6.5 How Not to Solve a Di!erential Equation of the Formdy
dx= f(y) . . . . . . . . . . . . . . 44
4 Modelling and Calculus 4 MAC 4Relating written word descriptions of real world physical conditions to the description ofthe problem in the language of mathematics and using these descriptions to find solutionsto the physical problem. 45
4.1 Finding Conditions in Questions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45
4.1.1 Exercises . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50
4.2 Ten Important Steps for Solving Modelling Questions Posed in Words . . . . . . . . . . . . . . . 52
5 Answers to Selected Exercises 60
5.1 Answers to Exercises 1.1.2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 60
5.2 Answers to Exercises 1.2.3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61
5.3 Answers to Exercises 1.3.2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63
5.4 Answers to Exercises 1.3.4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 64
5.5 Answers to Exercises 2.1.4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65
5.6 Answers to Exercises 2.2.2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 66
5.7 Answers to Exercises 2.2.5 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68
5.8 Answers to Exercises 2.3.2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68
5.9 Answers to Exercises 2.3.4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68
5.10 Answers to Exercises 3.1.1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68
5.11 Answers to Exercises 3.3.1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69
5.12 Answers to Exercises 3.4.1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69
5.13 Answers to Exercises 3.3.1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71
5.14 Answers to Exercises 3.6.2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71
5.15 Answers to Exercises 3.6.4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71
5.16 Answers to Exercises 4.1.1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72
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Chapter 1
Modelling and Calculus 1 MAC 1The interpretation and translation ofnatural and real world problems thatare described in words into aspecification and description of themodelling problem in the language ofmathematics
1.1 Rates of Change and Derivatives
1.1.1 Identifying The Di!erence Between a Quantity and the Rate of Change ofThat Quantity
Imagine a block of ice put in one of your classrooms.
The block of ice will melt.
The warmer the room the quicker the ice will melt.
How do we write this as an equation?
Let us say the volume of the block of ice is given by V .
Then the rate at which the block will melt will bedV
dt, where t is the time.
Remember thed
dtrepresents how quickly something changes.
The rate of change of volume, in words, is represented bydV
dtin mathematics.
Now the temperature of the room influences how quickly the ice will melt.
The temperature does not change the volume of ice instantaneously. A hot room doesn’t mean there will be noice straight away.
So the temperature of the room influencedV
dtnot V directly.
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In nature and the physical world often one quantity will influence the rate of change of another.
Here we are making the distinction between a quantity and how quickly that quantity changes. These are notinter-changable concepts.
There may be lots of ice in a freezer. In which case the volume is large but the ice is changing very slowly.
There may be an iceberg which has drifted to a location with a warm climate in which case there is lots of icechanging very quickly.
There may be an ice cube in a cold slushy drink in which case there is little ice changing slowly.
There may be an ice cube in a warm beer in which case there is little ice that will change rapidly.
This distinction between the amount or quantity of a substance, and the rate of change of that substance is acritical concept for understanding modelling and calculus.
In written words expressions like rate, rate of change, speed, acceleration, how quickly, how slowly,how fast, amongst others may indicate a derivative in mathematics.
1.1.2 Exercises
In the following sentences identify which part, or parts, of the sentence representsdx
dtor the derivative of a
quantity.
For each question you need to make a distinction between which part of the question describes the quantityof something in the problem and which parts describe the rate of change of that quantity in the problem; justas we made a distinction between the volume of ice and the rate at which the volume of ice changes in theexamples above.
1. A cold sausage is placed in an oven. The rate of increase of temperature of the sausage will depend onhow hot the oven is.
2. The rate of change of concentration of salt in a cell will depend on the di!erence between the concentrationof salt in the cell and in the concentration of salt in the environment.
3. The rate at which a human body produces insulin will depend on the concentration of sugars in the blood
4. How fast a car travels will depend on the rate at which fuel is being taken from the fuel tank and fed tothe engine.
5. How fast a car accelerates or changes velocity depends on the rate of change of the rate at which fuel isbeing taken from the fuel tank and fed to the engine.
6. A swimming pool, which is initially full of water, is drained through a hole in the bottom of the pool.The rate at which the depth of water drops will depend on the the pressure at the bottom of the pool andhence will depend on the depth of water the water in the pool.
7. A ballon is filled with air and then allowed to deflate. The larger the balloon the more pressure the airwill exert. The rate of change of the volume of the balloon will depend on the diameter of the balloon.
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1.2 What is a Di!erential Equation?
1.2.1 Description of a Di!erential Equation
In nature, very often one property of a system will influence the rate of change of another property.
For instance if we place a hot pie in a warm room the rate of change of the temperature of the pie will dependon how cold or warm the room is. If the pie is put in a freezer the pie will cool quickly. If the pie is put in awarm room it will cool more slowly. If placed in an oven it will cool slowly or even heat up, depending on howhot the oven is, and in this case how hot the pie is.
The rate of change of the temperature of the pie will depend on the temperature of the room.
Many, many physical, chemical, electrical, biological and other natural systems can be well modeled by rela-tionships between one property of the system and the rate of change of another.
Many, many physical, chemical, electrical, biological and other natural systems can be wellmodeled by relationships between one property of the system and the rate of change ofanother.
For these reasons we need to incorporate derivatives into our equations.
A di!erential equation is an equation which involves a derivative of one of the variables.
1.2.2 Constant Rate of Change
If we put a hose in a swimming pool and turn the tap on full the pool will fill up.
If the tap delivers water at, let’s say, 1000 litres every hour and this rate doesn’t change then the volume ofwater in the pool will change by a certain amount in any given time period.
If the volume of water in the pool is V then the rate of change of V will be constant.
In mathematics this idea is simply written as:dV
dt= c,
where c is a constant and t is time.
This mathematical expression has an equal sign hence it is called an equation.
The equation also involved a derivativedV
dthence it is called a di!erential equation.
The expressiondV
dt= c,
is an equation and has a derivative of one of the variables; hence we call it a di!erentialequation.
If a pool initially has 2000 litres of water in it and then has 3000 litres of water after constantly filling for 1hour and 4000 litres of water after 2 hours and 6000 litres after 4 hours then
dV
dt= 1000
litres
hour,
or, for V measured in litres and t measured in hours we just write
dV
dt= 1000.
Here the change in volume for any fixed period of time is the same. The volume changes by 1000 in any hour.The rate of change in volume will depend on how much we turn the tap on. If we turn-o! the tap a bit the ratewill decrease, but the volume will not.
The volume of water in the pool is di!erent than the rate of increase of volume.The rate at which the water enters the pool may be 1000 litres per hour, but the volume in the pool is never1000 litres.
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1.2.3 Exercises
For the following worded questions identify which parts of the question represents the derivative of a quantity,which part represents the quantity itself, which part represents the equality, and which feature of the problemstell us what the rate of change will be.
1. A ballon fills with air such that the rate of change of volume of the balloon is equal to 2000 litres perminute.
2. The rate of change of temperature of a cold beer is equal to the di!erence in temperature of the beer andthe room.
3. The rate at which a swimming pool is filled is equal to a constant times the opening in the tap.
4. A bowling ball is thrown out of an aircraft and falls such that the rate of change of the speed is increasingby 9.8 metres per second every second. (This means that the object, which initially is not falling at allwill be falling at 9.8 metres per second after 1 second, and will be falling at 19.6 metres per second after2 seconds etcetera.)
5. A balloon deflates such that the rate of change of volume of the balloon is equal to a constant times thevolume of the balloon. In this case as the balloon deflates there is less pressure exerted by the balloon onthe air inside.
6. The rate of change of concentration of alcohol in the blood stream of a person who has stopped drinkingis constant.
7. The change of speed of an object falling to Earth will increase at a constant rate of 9.8 metres per secondevery second. (This means that if the object is dropped from rest then it will be falling at a speed of9.8 metres per second after one second and then be falling at a speed of 19.6 metres per second after 2seconds.)
8. The rate of change of the wind-speed (where the wind-speed is positive if it is onshore and negative ifis or o!shore) in an idealized costal region will be dependent on the di!erence in the temperature of theland and the ocean.
9. The rate at which a small shark population increases will equal a constant times the number of fish intheir habitat
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1.3 Proportionality
1.3.1 Description of Proportional Quantities
The diameter of a circle is always two times the radius.
For a circle of radius 1 metre the diameter is 2.
For a circle of radius 1 light year the diameter is 2 light years. A light year is how far light travels in a year (ina vacuum). This is a pretty big circle.
Likewise there is a relationship between the distance around a circle (the circumference) and the diameter.
For a tractor wheel of diameter of 1 metre the circumference is about 3.141 . . .metres = !m.For a ferris wheel of diameter of 10 metres the circumference is about 31.41 . . .metres = 10!m.
If a fixed change in one quantity always leads to, a not necessarily equal, but fixedchange in another we say that the two quantities are proportional.
For instance if we change the radius of a circle by 1 metre then we will change the diameter by 2 metres. If weincrease the diameter of a circle by 1 metre then we will change the circumference by 3.141 . . . m or ! m.
We say that the diameter is proportional to the radius or in mathematical symbols we write
diameter " radius or d " r,
where d is the diameter of the circle and r is the radius.
This means that the diameter will be equal to a constant times the radius. Here
d = 2r.
Likewise the circumference is proportional to the diameter of a circle or
circumference " diameter or c " d,
where c is the circumference. Here the circumference is equal to a constant times the diameter, and the constantis the most famous constant of proportionality, !. We write
c = !d
If two quantities A and B are proportional we write
A " B,
which reads A is proportional to B.
If A and B are proportional then A will be equal to a non-zero constant times B or
A = k #B,
which reads A is equal to a non zero constant k times B.
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1.3.2 Exercises
Are the following quantities proportional?
1. The diameter of a sphere and the radius of a sphere.
2. The circumference of a circle and the diameter of a circle.
3. The circumference of a great circle (the largest circumference of a sphere) and the diameter of a sphere.
4. The perimeter of a square and the length of a side of a square.
5. The area of a square and the side length of a square.
6. The area of a circle and the radius of a circle.
7. The height and the corresponding weight of each person in a group of 100 students.
8. The number of people passing a maths class and the size of that maths.
9. The area of a circle and the radius-squared of the circle.
10. The volume of a cube and the volume of the biggest sphere that can just be contained in that sphere.
1.3.3 Constants of Proportionality
If A is proportional to B then
A = k #B,
where k $= 0 is called the constant of proportionality.
It is generally specified that the constant of proportionality not be equal to zero. If a constant c could be zerothen A = c#B would mean that A = 0 and A would be identically equal to zero, no matter what the value ofB. For this circumstance the value of A would not be dependent on B or the two quantities A and B would notbe dependent. Since we reasonably expect two quantities that are proportional to be dependent we generallyexclude the case of k = 0 from the definition.
Perhaps the most famous constant of proportionality is the constant !, which is about 3.141 . . . .
We know the diameter d and circumference of a circle c are proportional, or c " d in this case
c = !d .
So ! is the constant of proportionality between the diameter and circumference of a circle.
In fact this can be used as a definition of the important constant !.
! is the geometric constant of proportionality (for Euclidean space).
For a fixed change of say 1 metre in diameter, the circumference will change by 3.141 . . . or ! metres.
If we increase the diameter of a Ferris wheel from 10 metres to 11 meters it will be 3.141 . . . metres larger aroundthe circumference.
In fact if we change the diameter of any Ferris wheel by 1 metre, no matter how big or small, the circumferencewill change by ! metres.
This is precisely why, when you pump up the tyres on a car or a bike the speedo will read slower when you aregoing at exactly the same speed along the road. Or another way of saying this is that for the same reading onthe speedo “more pumped up” tyres will make the car travel faster.
If we graph the diameter of a ferris wheel with the circumference the graph will be a straight line. Every timewe increase d by one metre c will increase by ! metres.
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The graph of any two proportional quantities with A on the horizontal axis B on the vertical axis, with sayA = k # B will be a straight line with gradient k. If we change A by "A this will lead to a change in B ofk #"B
1.3.4 Exercises
For each of the following sets of quantities find the constant of proportionality
1. The radius of a sphere and the diameter of a sphere.
2. The diameter of a sphere and the circumference of a great circle ( the largest circumference of a sphere).
3. The length of a side of a square and the distance around the perimeter of a square.
4. The radius of a circle and the circumference of a circle.
5. The volume of a cube and the side length cubed of the cube.
6. The volume of a sphere and the radius of a sphere cubed.
7. An inch and a millimetre.
8. A litre and a cubic metre.
9. The side length of a square and the diagonal of a square.
10. The area of a square and the area of the largest circle that can wholly be contained in that square.
11. The volume of a cube and the volume of the biggest sphere that can wholly be contained in that cube.Hint: for d half the side length of the cube and r the radius of the sphere then r2 = d2 + 2d2.
12. What constant of proportionality would you choose for the following quantity. The number of peoplepassing a maths class and the size of that maths class.
13. What constant of proportionality would you choose for the following quantity. The number of peoplefailing a maths class and the size of that maths class.
14. The area of a circle and the radius squared of the circle.
Chapter 2
Modelling and Calculus 2 MAC 2Understanding the concepts and ideasof di!erential equations and theirsolutions in terms of written worddescriptions of the di!erentialequations and the concepts of solving adi!erential equation.
2.1 Di!erential Equations as Questions: Various Variables
2.1.1 Solution Function and Independent Variable
To work out what question a di!erential equation is asking we look at the symbol at the top of the derivative,
fordy
dxthis is y. For
df
dtthis is f . We may want to eventually find this function. Let’s call this the solution
function.
We then look at the thing we are di!erentiating with respect to, or the symbol on the bottom of the derivative.
Fordy
dxthis is x. For
df
dtthis is t. Here we will call this the independent variable, because (here) we want to
find the solution function in terms of this independent variable.
Here we want to find the solution function in terms of the independent variable.
Fordy
dxwe want to find y in terms of x.
Fordf
dtwe want to find f in terms of t.
2.1.2 Independent Variables and Dependent Variables
The reason that we call one variable independent and one variable a dependent variable is that they will servedi!erent rolls in the solution.
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For instance if we find y in terms of x, let’s say for instance we find y = x2 + 3x then we can change the xvariable and simply calculate the new value for y. y is dependent on x and we think of x, as being able to bechanged independently.
For the same function y = x2 + 3x if we change y it is quite an involved process to find the new value of x.Changing y results in a more involved calculation to find x.
Even though, strictly speaking, both variable are dependent on the other, through our equation; since we can’tchange one without the other, if we change the independent variable we can simply use our formula to find thenew value of the dependent variable.
In some instances we may need to find the variable on the bottom of the derivative in terms of the variableon the top. In this case then the roles of the variables will be reversed. Here, to start with, we stick with thesolution function on the top and the independent variable on the bottom of the derivative.
2.1.3 Alternative Notations for Di!erential Equations
There are many di!erent notations for a derivative. We can write the derivativedy
dxas y!(x).
So for a derivative of the form X !(t) for instance, we want to find the solution function X in terms of theindependent variable t.
For this alternative notation:
For Y !(x) we want to find Y in terms of x.
For X !(t) we want to find X in terms of t.
For a di!erential equation of the formdy
dx= 3x2, we want to find a solution function y as a function of x.
For a di!erential equation of the form X !(t) = 20X, we want to find a solution function X as a function of t.
Example 1
For the di!erential equationdy
dx= 4x2 + 2x,
identify the solution function and the independent variable.
SolutionHere y is the solution function and x is the independent variable. We want to find y as a function of x.
Example 2
For the di!erential equationf !(z) = 2z2,
identify the solution function and the independent variable.
SolutionHere f is the solution function and z is the independent variable. We want to find f as a function of z.
Example 3
For the di!erential equationX !(t) = 15X,
identify the solution function and the independent variable.
SolutionHere X is the solution function and t is the independent variable. We want to find X as a function of t.
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2.1.4 Exercises
For the following di!erential equations find the solution function(s) and the independent variable.Note: you do not need to solve the di!erential equations here just name the solution function and the independentvariable.
1.dy
dx= x
2.dy
dx= y
3.dy
dx= 3x2 + 5y2
4.dy
dx= x
5.dx
dy= y2 + 2x# y
6.dx
dt# x+ t = 0
7.dx
dt= 3x2 + 4t
8. 0 =dz
dy+ 2y # z
9. 3 + 7dz
dx+
!dz
dx
"2= 0
10.1dy
dx
+ 3y = 0
11.dx
dt+ y = t,
dy
dt+ x = t2
12. X !(t) = 4
13. X !(t) = X(t)
14. X !(t) + 3X(t) = t2
15. X !(Z) + Z #X = 0
16. Y !(Z) + 3 = Y (Z)
17. X !(t)%Xt = X3t2
18. X !(t) = X % Y , Y !(t) = Y %X + 2
19.d2X
dt2+
dX
dt+X
20. X !!(t) +X !(t) +X(t) = 0
Draft Version August 2011 c!2010 University of Sydney 14
2.2 Di!erential Equations as Questions
2.2.1 Di!erential Equations of the Formdy
dx= f(x) as Questions
With the solution function and independent variable in mind we look at the rest of the di!erential equation.
It is useful to think of a di!erential equation, not as a mathematical formula, but as asking a question in words.
Example 1
The di!erential equationdy
dx= 2x
is like asking the question:
Can you think of a function y, which is a function of x, such that when you di!erentiate thatfunction you get 2x?
Just one answer to this question is
y = x2,
or y(x) = x2. Since if you di!erentiate x2 you get 2x.
We could have also chosen y(x) = x2 + 1 for instance.
Example 2
The di!erential equationdy
dx= 3x2
is asking:
Can you think of a function y, which is a function of x, such that when you di!erentiate thatfunction you get 3x2?
Just one answer to that question is
y = x3.
Can you think of another?
Example 3
The di!erential equationdy
dx= 4x3 + 10x3
is asking:
Can you think of a function y, which is a function of x, such that when you di!erentiate thatfunction you get 4x3 + 10x3?
Draft Version August 2011 c!2010 University of Sydney 15
2.2.2 Exercises
For the following di!erential equations write down a simple sentence in words that represents a question thatthe di!erential equation is asking.
1.dy
dx= 2
2.dy
dx= 2x
3.dy
dx= sin(x)
4.dy
dx= 3x2
5.dy
dx= ex
6.dy
dx= x sin(x)
7.dy
dx+ 2x = 3
8. X !(t) = 3t2
9. Y !(z) = sin z + z
10. W !(t) + sin t = 15
11.dy
dx# x = 3
12.dy
dx# sin(x) = x sin(x)
13.dy
dx# ex = e2x
Below are some harder questions that can be answered by extending the ideas in this section.
14.
!dy
dx
"2= (3x2 + 2)2
15. X !(t) +X(t) = 3t2
16. [X !(t)]2 +X !(t) = 13
17.
#dy
dx
$2
# y + sin(x) = 0
18. Z !(Y )# Z(Y ) + 3Z(Y ) = Y 2
19. 2dy
dx+ 3y + sin(x) = 0
20. [X !(t)]2 +X(t) sin t = t2
Draft Version August 2011 c!2010 University of Sydney 16
2.2.3 Di!erential Equations of the Formdy
dx= g(y) as Questions
In all of our examples so far the right hand side has only involved independent variables. For the example abovethere are only xs on the right.
But there can be solution functions on the right as well.
Example 1
For instance we can have a di!erential equation such as
dy
dx= y.
This di!erential equation is, in essence, quite di!erent to the others we have discussed above. The equation canbe thought of as asking the question:
Can you think of a function y, which is a function of x, such that when you di!erentiate thatfunction you get the same function that you started with?
The function y = ex has derivativedy
dx=
d
dxex = ex = y.
So y = ex is a function that has itself as its derivative.
So y = ex is just one answer to our question—what function is its own derivative.
But again this is not the only function that answers our question.
The function y = 2ex has derivativedy
dx=
d
dx2ex = 2ex = y.
So y = 2ex is also a function that is its own derivative.
So y = 2ex is again just one answer to our question.
The functions y = ex and y = 2ex are answers to our question and there are many more. Other answers to thequestion “can you think of a function that is its own derivative” are y = 3ex, y = 24ex, y = %351ex.
Indeed the exponential function is unique as it is the only type of function, such that when you di!erentiate ityou get back the same function.
The only class of functions that are their own derivatives are the exponential functions of the form y(x) = Aex.Since
dy
dx=
d
dxAex = Aex = y
that is when we di!erentiate Aex we get back the same function we started with.
Hence Aex is the most general answer to our question.
The exponential function is the only type of function who’s derivative is the same as the function itself.
y(x) = constant# ex is the only type of function that is its own derivative.
Draft Version August 2011 c!2010 University of Sydney 17
Example 2
The di!erential equationdy
dx= 4y
is more complicated again. It is asking:
Can you think of a function y, which is a function of x, such that when you di!erentiate thatfunction, you get 4 times the function that you first thought of?
Just one function which answers our question is y = e4x, since heredy
dx=
d
dxe4x = 4 # e4x which is 4 times
the function we first thought of. Can you think of others (Example 1 provides a hint)?
Example 3
The di!erential equationdx
dt= x2 + 2x
is asking:
Can you think of a function x, which is a function of t, such that when you di!erentiate thatfunction you get the square of the function you first thought of plus 2 times the function that youfirst thought of?
The function which answers our question is x(t) =2
ce"2t + 1.
As we can see the solutions to di!erential equations get very complicated very quickly. In fact we can writedown very simple looking di!erential equations that do not have solutions in terms of simple functions. Onesuch example is f !(x) = ex
2
. There are many more.
In fact writing down di!erential equation can be thought of as a way of defining many special functions. The
di!erential equationdy
dx= y can be used as a definition for the function y(x) = ex and can be used to find the
important constant e = 2.718281828 . . ..
2.2.4 Di!erential Equations of the Formdy
dx= f(x)g(y) as Questions
Example 4
The di!erential equationdx
dt= 2tx
is asking:
Can you think of a function x, which is a function of t, such that when you di!erentiate thatfunction you get 2t times the function that you first thought of?
Just one function which answers our question is x = et2
, since heredx
dt=
d
dt
et2
= 2t# et2
which is 2t times
the function we first thought of.
Please note that you are not expected to solve these di!erential equations here. You shouldunderstand how to understand what a di!erential equation may be asking.
Draft Version August 2011 c!2010 University of Sydney 18
2.2.5 Exercises
1. Which question is the following di!erential equation asking in words?
dy
dx= 3x2
(a) Can you think of a function such that when you di!erentiate that function you get 3 times thefunction.
(b) Can you think of a function such that when you di!erentiate that function you get the square of thefunction.
(c) Can you think of a function such that when you di!erentiate that function you get 2 times the squareof the function.
(d) Can you think of a function such that when you di!erentiate that function you get 3 times the squareof the function.
(e) None of the above.
(f) All of the above.
2. Which question is the following di!erential equation asking in words?
dy
dx= 3y2
(a) Can you think of a function such that when you di!erentiate that function you get 2 times the squareof the function you first thought of .
(b) Can you think of a function such that when you di!erentiate that function you get 3 times the functionyou first thought of .
(c) Can you think of a function such that when you di!erentiate that function you get 3 times the squareof the function you first thought of .
(d) Can you think of a function such that when you di!erentiate that function you get the square of thefunction you first thought of.
(e) None of the above.
3. Which question is the following di!erential equation asking in words?
dx
dt= 3x2
(a) Can you think of a function such that when you di!erentiate that function you get 3t2
(b) Can you think of a function such that when you di!erentiate that function you get 3 times the functionyou first thought of .
(c) Can you think of a function such that when you di!erentiate that function you get the square of thefunction you first thought of.
(d) Can you think of a function such that when you di!erentiate that function you get 3 times the squareof the function you first thought of .
(e) Can you think of a function such that when you di!erentiate that function you get 2 times the squareof the function you first thought of .
(f) None of the above.
4. Which question is the following di!erential equation asking in words?
dx
dt= 3x2 + x3
(a) Can you think of a function such that when you di!erentiate that function you get 3t2 + t3
(b) Can you think of a function such that when you di!erentiate that function you get 3 times the functionyou first thought of plus that function cubed.
Draft Version August 2011 c!2010 University of Sydney 19
(c) Can you think of a function such that when you di!erentiate that function you get two times thesquare of the function you first thought of plus that function cubed.
(d) Can you think of a function such that when you di!erentiate that function you get 3 times the squareof the function you first thought of plus that function squared.
(e) Can you think of a function such that when you di!erentiate that function you get 3 times the squareof the function you first thought of .
(f) None of the above.
5. Match up the di!erent di!erential equations with their corresponding questions, written in words.
(a) Can you think of a function such that when you di!erentiate that function you get 3t2 + t3
(b) Can you think of a function such that when you di!erentiate that function you get 2 times the functionyou first thought of plus that function cubed.
(c) Can you think of a function such that when you di!erentiate that function you get two times thesquare of the function you first thought of plus that function cubed.
(d) Can you think of a function such that when you di!erentiate that function you get 3 times the squareof the function you first thought of plus that function squared.
(e) Can you think of a function such that when you di!erentiate that function you get 3 times the squareof the function you first thought of .
(i)df
dt= 2f2 + f3
(ii)dx
dt= 4x2
(iii)dy
dt= 3t2 + t3
(iv)dx
dt= 3x2
(v)dx
dt= 2x+ x3
Draft Version August 2011 c!2010 University of Sydney 20
2.3 Particular Solutions and General Solutions or Di!erentiating inReverse
2.3.1 The di!erence between General Solutions and a Particular Solution
For this section we will concentrate on di!erential equations that look like
dy
dx= f(x),
that is equations with the derivative on the left and a function of only the independent variable on the right.
Examples of these type of di!erential equations aredy
dx= 3x2 +2x or
dy
dx= 10x4 % sin(x), but with no solution
functions, or ys here, on the right.
Example 1
The di!erential equationdy
dx= 5 is asking; can you think of a function y(x) such that when you di!erentiate
that function you get 5.
Just one answer is y(x) = 5x as hered
dx5x = 5
If you know how to di!erentiate, answering these questions seems like we just need to apply the rules ofdi!erentiation in reverse.
This process is given the name anti-di!erentiation.
Anti-di!erentiation simply means apply the rules of di!erentiation in reverse,in order to solve our di!erential equations or answer our questions.
Seems simple so far, though there can be many answers to one question, just like the meaning of life.
Example 2
The di!erential equationdy
dx= 2x is asking; what y do we di!erentiate to get 2x?
We know y(x) = x2 is an answer to this question asd
dx
x2
= 2x. So we have one solution to this di!erential
equation.
But if we di!erentiate y = x2 + 1 for instance, we also haved
dx(x2 + 1) = 2x. This means that y = x2 + 1 is
also a solution to our di!erential equation. But so is y = x2 % 1, y = x2 + 10, y = x2 % 24.3, y = x2 + 1000000,y = x2 + ! and y = x2 % ! # 1000000.
There can be many solutions to just one di!erential equation.
If we di!erentiate any constant we get 0. So if we di!erentiate
y = x2 + any constant
we getd
dx(x2 + any constant) = 2x.
So there are lots of answers to our questiondy
dx= 2x. In fact there are an infinite number of them.
The most general solution to this di!erential equation is y = x2 + c, where c is a constant.
Draft Version August 2011 c!2010 University of Sydney 21
The constant c, as used here, is called the constant of integration.
Since there may be lots of solutions to any one di!erential equation we use special names for each type.
The solution y = x2+ c is called the general solution of the di!erential equationdy
dx= 2x.
As it is the most general solution to the di!erential equation.
Any one of these solutions on there own, such as, y = x2, y = x2 + 100, y = x2 % ! # 10000000000000000 areall still solutions to the di!erential equation.
Any one of these solutions is called a particular solution to the di!erential equation.
y = x2 is a particular solution to the di!erential equation. y = x2 + 100 is also a particular solution to thedi!erential equation. y = x2 % ! # 10000000000000000 is also a particular solution to the di!erential equation.
The solution y = x2 is called a particular solution of the di!erential equationdy
dx= 2x.
As it is the just one solution to the di!erential equation.
2.3.2 Exercises
1. For the di!erential equationdy
dx= 3x2
which of the below are particular solutions?
(a) y = x3
(b) y = x3 % 10000000
(c) y = x3 % !
(d) y = x2 + 20000000
(e) y = x3 % c
(f) None of the above.
(g) All of the above.
2. For the di!erential equationdy
dx= 4x3
which of the below are particular solutions?
(a) y = x4 + 10
(b) y = x4 + !
(c) y = x3 + c
(d) y = x3 % c
(e) y = 4x3 + c
(f) None of the above.
(g) All of the above.
3. For the di!erential equationX !(t) = sin(t)
which of the below are general solutions?
(a) X(t) = cos(t) + c
(b) X(t) = %cos(t) + 10
(c) X(t) = %cos(t) + c
(d) X(t) = cos(t) + 2d
(e) X(t) = %cos(t) + 2d
(f) None of the above.
(g) All of the above.
Draft Version August 2011 c!2010 University of Sydney 22
2.3.3 Particular Solutions and General Solutions in General
The most general solution to a di!erential equation is called the general solution.
For the di!erential equations with only the first derivative, in these notes, the generalsolution will involve a constant such as c above.
The constant c, as used here, is called the constant of integration.
Any single solution to a di!erential equation is called a particular solution.
The particular solution will not involve a constant of integration, such as c above.
Summary of Terminology For Di!erential Equations
dy
dx= f(x) is called a di!erential equation. There are many other types.
y =
%f(x) dx is called the general solution of the di!erential equation. The integral will
involve a constant c say.c is called the constant of integration.
If we evaluate c, for instance if c = 0 then y =
%f(x) dx, with c = 0, is called a particular
solution of the di!erential equation.The process of answering a question about the derivative of a function that we are usinghere is called anti-di!erentiation.
Example
dy
dx= 5x2 is called a di!erential equation.
y =5
3x3 + c is called the general solution of the di!erential equation.
c is called the constant of integration.
If we evaluate c, for instance if c = 0 then y =5
3x3 is called a particular solution of the
di!erential equation. y =5
3x3 + 10 is also a particular solution.
The process we are using of answering a question about the derivative of a function is calledanti-di!erentiation.
Draft Version August 2011 c!2010 University of Sydney 23
2.3.4 Exercises
The following mathematical expressions, that are labelled (a) to (f), are just part of a solution to a probleminvolving a di!erential equation.Match up each mathematical expression with the appropriate description in words, labelled (i) to (vi).
Please note: In general you should provide answers with descriptions of the solution in words aswell as mathematics.
As an example of how to set out solutions in words and mathematics see Ten Important Steps for SolvingModeling Questions Posed in Words
1. For the di!erential equationdy
dx= 2x
(a)dy
dx= 2x
(b) y = x2 + c
(c) y = x2 + 5
(d) c
(e) c = 5
(f) y = x2
(i) Di!erential Equation
(ii) Particular Solution
(iii) General solution
(iv) Particular Solution
(v) Constant of Integration
(vi) Evaluation of constant of integration
2. For the di!erential equationdy
dx= 5x4
(a) c = 5
(b) y = x5 + c
(c) y = x5 + 5
(d) c
(e)dy
dx= 5x4
(f) y = x5 + c
(i) General solution
(ii) Particular Solution
(iii) Di!erential Equation
(iv) Constant of Integration
(v) General Solution
(vi) Evaluation of constant of integration
3. For the description of a di!erential equation, given by the following description;
“Can you think of a function such that when you di!erentiate that function with respect tot you get sin(t).”
match up each mathematical expression labelled (a) to (f) with the appropriate description in words,labelled (i) to (vi), if an appropriate description exists.
(a) X = cos(t) + c
(b) X = % cos(t)
(c)dt
dx= sin(t)
(d) X = % cos(t) + c
(e)dX
dt= sin(t)
(f) X = % cos(t) + 15
(i) General solution
(ii) Particular Solution
(iii) Di!erential Equation
(iv) Constant of Integration
(v) Particular Solution
(vi) Evaluation of constant of integration
Draft Version August 2011 c!2010 University of Sydney 24
4. For the description of a di!erential equation, given by the following description;
“Can you think of a function such that when you di!erentiate that function with respect tox you get x ex + ex.”
match up each mathematical expression labelled (a) to (f) with the appropriate description in words,labelled (i) to (vi), if an appropriate description exists.
(a)dy
dx= x ex + ex + c
(b) Y = x ex + c
(c) Y = x ex % 42
(d) Y !(x) = x ex + ex + c
(e) Y !(x) = x ex + ex
(f) Y (x) = x ex + e!
(i) General solution
(ii) Particular Solution
(iii) Di!erential Equation
(iv) Constant of Integration
(v) Particular Solution
(vi) Evaluation of constant of integration
Chapter 3
Modelling and Calculus 3 MAC 3Solving some di!erential equations byusing the concepts and interpretationsof a di!erential equation to find asolution or an answer posed by thedi!erential equation.
3.1 Solving Di!erential Equations of the Formdy
dx= f(x) Using Dif-
ferentiation in Reverse
The most important step in solving di!erential equations, at least at the beginning, is to understand what adi!erential equation represents and what it is asking.
The second most important step in starting to solve di!erential equations is understanding the terminology andnotation used.
We now use these ideas to solve some simple di!erential equations.
Here we concentrate on di!erential equations of the formdy
dx= f(x).
For these di!erential equations the right hand side is always some function of x, likedy
dx= 2x,
dy
dx= 3x2 etc.̇
To solve a di!erential equation of this form we are asked the question:
What function y, which is a function of x, has a derivative given by f(x).
If you know various derivatives this may be just a matter of, remembering derivatives, or looking up di!eren-tiation tables.
Example 1
Find one solution of the di!erential equation
dy
dx= cos(x).
From the di!erentiation tablesd
dxsin(x) = cos(x), so a solution is y(x) = sin(x).
25
Draft Version August 2011 c!2010 University of Sydney 26
Example 2
For the di!erential equationF !(t) = 3e3t
find one particular solution.
From the di!erentiation tablesd
dte3t = 3e3t, so a particular solution is F (t) = e3t.
Draft Version August 2011 c!2010 University of Sydney 27
3.1.1 Exercises
By using the di!erentiation tables identify which one of the options are particular solution to the di!erentialequations.
1.dy
dx= 10
(a) y = 10x+ c
(b) y = 10x2
(c) y = 10x% c
(d) y = 10x% !
(e) None of the above.
2.dy
dx= 6x
(a) y = 6x2
(b) y = 6# x2/2 + c
(c) y = 3x2 + c
(d) y = 3x2
(e) None of the above.
3.dy
dx= 3# 5x4
(a) y = 3x5
(b) y = 3# x5/5
(c) y = 3# x5/5 + c
(d) None of the above.
4.dy
dx= 6x5
(a) y = 6x6
(b) y = 6x6 + c
(c) y = 6# x6/5
(d) y = x6 + c
(e) None of the above.
5.dy
dx= 10# 14x13
(a) y = 10x14 + c!
(b) y = 10x14 + c
(c) y = 10x14 % 100000!
(d) y = 10x14
(e) all of the above
(f) none of the above.
Draft Version August 2011 c!2010 University of Sydney 28
6.dX
dt= et
(a) y = ex
(b) y = ex + c
(c) y = et + c
(d) X = et + !
(e) none of the above.
7.
Y !(x) = 5x4 + 3x2
(a) Y (x) = x5 + x3
(b) Y (x) = x5 + x3 + 42
(c) Y (x) = x5 + x3 % e42!
(d) Y (x) = x5 + x3 + c
(e) none of the above.
8.
X !(t) =1
t
(a) X !(t) = ln(t)
(b) X(t) = ln(t) + c
(c) X(t) = ln(t)% e355!+ln(42)
(d) Y (x) = ln(x)% 1
(e) none of the above.
9.dy
dx= sec2(x)
(a) y = sec(x)
(b) y = sec2(x)
(c) y = tan(x) + c
(d) y(x) = tan(x)% 53
(e) none of the above.
10.dX
dt= 2t sec2(t2)
(a) X(t) = tan(t2)
(b) X = tan(t2)% 51!
(c) X = tan(t2) + 100000000000000000000000000000
(d) X = tan(t2) + 0
(e) none of the above.
Draft Version August 2011 c!2010 University of Sydney 29
3.2 Di!erentiation Tables
No. General Rule Example 1 Example 2 Example 3
(1)d
dx(of any constant c) = 0
d
dx1 = 0
d
dx10 = 0
d
dx! # 1000000001 = 0
(2)d
dxx = 1
d
dtt = 1
d
dzz = 1
(3)d
dxx2 = 2x
d
dtt2 = 2t
d
dff2 = 2f
(4)d
dxx3 = 3x2 d
dtt3 = 3t2
d
duu3 = 3u2
(5)d
dxxn = nxn"1 d
dxx4 = 4x3 d
dxx"1 = %1x"2 = % 1
x2
d
dxx16 = 16x15
(6)d
dxcf(x) = c# df(x)
dx
d
dx10x = 10#1 = 10
d
dx2x2 = 2# 2x = 4x
d
dx!x0.3 = ! # 0.3x"0.7
(7)d
dxex = ex
d
dtet = et
d
dueu = eu
d
dz! # ez = ! # ez
(8)d
dxeax = aeax
d
dte3t = 3e3t
d
due10u = 10e10u
d
dze"2.3z = %2.3e"2.3z
(9)d
dxef(x) = ef(x)
d
dxf(x) = f !(x)ef(x)
d
dxex
2
= 2xex2 d
dxe2x
3
= 6x2e2x3 d
due!u
!6
= %6!u"7e!u!6
(10)d
dxln(x) =
1
x
d
dt3 ln(t) = 3# 1
t
d
dw! ln(w) =
!
w
(11)d
dxln(f(x)) =
1
f(x)
d
dxf(x) =
f !(x)
f(x)
d
dxln(x2) =
1
x2# 2x
d
dxln(5x4) =
1
5x4# 20x3 d
dx3 ln(!x"6) =
3
!x"6#%6!x"7
Draft Version August 2011 c!2010 University of Sydney 30
Di!erentiation Tables Continued
No. General Rule Examples
(12)d
dxsin(x) = cos(x)
d
dtsin(t) = cos(t)
d
dx355 sin(x) = 355 cos(x)
d
dz% !2 sin(z) = %!2 cos(z)
(13)
d
dxsin( f(x) ) = cos( f(x) )# d
dxf(x)
= cos( f(x) ) f !(x)
d
dxsin(2x) = cos(2x)# 2
d
dxsin(5x2 % 4x) = cos(5x2 % 4x)#(10x% 4)
d
dx24 sin(e3x) = 24 cos(e3x)# 3e3x
(14)d
dxcos(x) = % sin(x)
d
dx24 cos(x) = %24 sin(x)
d
dz(%3!5 cos(z)) = 3!5 sin(z)
d
df!e5 cos(f) = %!e5 sin(f)
(15)
d
dxcos( f(x) ) = % sin( f(x) )# d
dxf(x)
= % sin( f(x) ) f !(x)
d
dxcos(2x) = % sin(2x)# 2
d
dxcos(%4x3 + 3x2 % 5x) = % sin(%4x3 + 3x2 % 5x)# (%12x2 + 6x% 5)
d
dx24 cos(e"!x) = %24 sin(e"!x)#%!e"!x = 24!e"!x sin(e"!x)
Draft Version August 2011 c!2010 University of Sydney 31
Di!erentiation Tables Continued
No. General Rule Examples
(16)d
dxtan(x) = sec2(x)
d
dxtan(t) = sec2(t)
d
dx42 tan(x) = 42 sec2(x)
d
dz4!2 tan(z) = 4!2 sec2(z)
(17)
d
dxtan( f(x) ) = sec2( f(x) )# d
dxf(x)
= sec2( f(x) )f !(x)
d
dxtan(x3) = sec2(x3)# 3x2
d
dxtan(4x3 % 3x+ 2) = sec2(4x3 % 3x+ 2)# (12x2 % 3)
d
dx% 5692!2 tan(e53!x) = %5692!2 sec2(e53!x)# 53!e53!x
Draft Version August 2011 c!2010 University of Sydney 32
3.3 Solving Di!erential Equations of the Formdy
dx= f(x) Using In-
tegration
A di!erential equation of the formdy
dx= f(x) may be solved by using di!erentiation in reverse that is by
anti-di!erentiation by asking:
What function y(x) can be di!erentiated to give f(x)?
But we can also try to solve this type of equation by using integration.
We can “undo” thed
dxon the left by integrating. If the function on the right, that is f(x) can be integrated
(over the interval of x) then we can find a solution to the di!erential equation.
We start with the di!erential equationdy
dx= f(x).
We then integrate both sides of the equation with respect to the independent variable, here x.
Given certain conditions if we performing the same operation to both sides of the equation then the two sidesof the equation will remain equal. This is analogous to multiplying both sides of an equation by 2, or takingthe square of both sides of the equation. So long as we perform precisely the same operation to both sides ofthe equation the equality remains valid.
You must always integrate both sides of the equation with respect to the same variable.
%dy
dxdx =
%f(x) dx.
Giving the solution;
y =
%f(x) dx.
For this special case then we can use integration or integration tables to find a solution for the di!erentialequation.
Example 1
Question
Find the general solution to the di!erential equation
dy
dx= x2
Answer
Step 1 Integrate both sides of the di!erential equation with respect to the independent variable x,%
dy
dxdx =
%x2 dx
Step 2 perform the integration,
y =
%x2 dx
=1
3x3 + c,
where c is a constant.
Step 3 State the answer in words and mathematics.
The general solution is
y =1
3x3 + c.
Draft Version August 2011 c!2010 University of Sydney 33
Example 2
Question
Find the general solution to the di!erential equation
dX
dt=
%2t
3% t2
Answer
Step 1 Integrate both sides of the di!erential equation with respect to the independent variable t,%
dX
dtdt =
% %2t
3% t2dt
Step 2 perform the integration,
X(t) =
% %2t
3% t2dt
= ln |3% t2|+ c,
where c is a constant.
Note: here we are using the rule that says if we have a function on the bottom ofa fraction and the derivative of that function on the top then the integral of thatfraction is the natural log of the absolute value of that function or in the language ofmathematics :
%f !(x)
f(x)dx = ln(|f(x)|) + c
So for our integral we need the %2t on the top to use this rule.
Step 3 State the answer in words and mathematics.
The general solution isX(t) = ln |3% t2|+ c,
where c is a constant.
In General:
To solve a di!erential equation of the formdy
dx= F (x) we may be able to find the integral
of F (x). Lets say&F (x) dx = f(x) + c . The steps are:
Step 1 Integrate both sides of the di!erential equation%
dy
dxdx =
%F (x) dx
Step 2 perform the integration,
y =
%F (x) dx
= f(x) + c,
where c is a constant.
Step 3 State the answer in words and mathematics.
The general solution isy = f(x) + c.
Draft Version August 2011 c!2010 University of Sydney 34
3.3.1 Exercises
By integrating both sides of the di!erential equations below, find the most general solutions. The integrationtables may be useful for finding the integrals.Note for each of these exercises you should set out the solution indicating in words what youare doing at each stage. The explanation of what you are doing in words is often awarded marks in anexamination.
1.dy
dx= 3x3
2.dy
dx= 2
3.dy
dx= 5x6 % 16x3
4.dy
dx= !x2
5.dy
dx= cos(x)
6.dy
dx= e5x
7.dy
dx= 2x+ cos(x)
8.dy
dx= cos(3x)
9.dy
dx= cos(x2)# 2x
10.dy
dx= ex
2
# 2x
11.dy
dx=
1
x5# 5x4 + sin(3x5)# 15x4
Draft Version August 2011 c!2010 University of Sydney 35
3.4 Checking Your Solution
We can always check if a solution is correct by substituting the solution or answer into the di!erential equation(d.e.) and di!erentiating.
Example 1
To check the answer y =1
3x3 + c to the di!erential equation
dy
dx= x2 we simply substitute the answer into the
di!erential equation.
Check
Left hand side of d.e. isd
dxy =
d
dx
#1
3x3 + c
$
=1
3# 3x2 +
d
dxc
= x2 + 0
= x2
= Right hand side of d.e.
So our solution works when we put it back into the di!erential equation.
You should always check your answer by substituting the solution back into the di!erential equation.When answering questions in an exam it may be best to leave this step until the end, if time permits.
If you are ever asked to verify or check if a solution satisfies a di!erential equationsimply substitute the solution into the di!erential equation and show that it is satisfied.In many instances this will be much simpler than solving the di!erential equation.
Draft Version August 2011 c!2010 University of Sydney 36
3.4.1 Exercises
For each of the solutions below verify that the solution satisfies the di!erential equationNote you are only required to substitute the solution into the equation and show that is works.
1. Solution y(x) =3
4x4, di!erential equation
dy
dx= 3x3.
2. Solution y(x) = 2x+ c , di!erential equationdy
dx= 2
3. Solution y(x) =5
7x7 % 16
4x4, di!erential equation
dy
dx= 5x6 % 16x3
4. Solution y(x) = !x3
3+ c, di!erential equation
dy
dx= !x2
5. Solution y(x) = sin(x) + 3, di!erential equationdy
dx= cos(x)
6. Solution y(x) =1
5e5x, di!erential equation
dy
dx= e5x
7. Solution y(x) =x2
2+ sin(x), di!erential equation
dy
dx= x+ cos(x)
8. Solution y(x) =1
3sin(3x), di!erential equation
dy
dx= cos(3x)
9. Solution y(x) = sin(x2)% !, di!erential equationdy
dx= cos(x2)# 2x
10. Solution y(x) = ex2
+ c, di!erential equationdy
dx= ex
2
# 2x
11. Solution y(x) = x5 cos(15x4), di!erential equationdy
dx= 5x4 cos(15x4)% 60x8 sin(15x4)
Draft Version August 2011 c!2010 University of Sydney 37
3.5 Integration Tables
No. General Rule Example 1 Example 2
(1)
%kdx = kx+ c
%2dx = 2x+ c
%10!dx = 10!x+ c
(2)
%kxdx = k
x2
2+ c
%3xdx = 3
x2
2+ c
%% 5xdx = %5
x2
2+ c
(3)
%kx2dx = k
x3
3+ c
%% 4x2dx = %4
x3
3+ c
%!x2dx = !
x3
3+ c
(4)
%kxndx = k
xn+1
n+ 1+ c n $= %1
%2x3dx = 2
x4
4+ c
%!x"5dx = !
x"4
%4+ c = % !
4x4+ c
%1
x2dx =
%x"2dx =
x"1
%1+ c = % 1
x+ c
(5)
%kf(x)dx = k
%f(x)dx
%5x16dx = 5
%x16dx = 5
x17
17+ c
%% !2
214x5!dx = % !2
214
%x5!dx = % !2
214
x5!+1
5! + 1+ c
(6)
%1
xdx = ln(|x|) + c interval of integration not across x = 0
%5# 1
xdx = 5 ln(|x|) + c
%% 10
xdx = %10 ln(|x|) + c
(7)
%f !(x)
f(x)dx = ln(|f(x)|) + c interval of integration not across f(x) = 0
%2x
x2dx = ln(|x2|) + c
%30x5
5x6dx = ln(|5x6|) + c
%cos(x)
sin(x)dx = ln(| sin(x)|) + c
%15e5x
3e5xdx = ln(|3e5x|) + c
Draft Version August 2011 c!2010 University of Sydney 38
Integration Tables Continued
No. General Rule Example 1 Example 2
(8)
%cos(x)dx = sin(x) + c
%cos(t)dt = sin(t) + c
%!2 cos(t)dt = !2 sin(t) + c
(9)
%cos(kx)dx =
1
ksin(x) + c
%cos(2x)dx =
1
2sin(2x) + c
%cos
#1
2x
$dx = 2 sin
#1
2x
$+ c
(10)
%sin(x)dx = % cos(x) + c
%sin(t)dt = % cos(t) + c
%235 sin(t)dt = %235 cos(t) + c
(11)
%sin(kx)dx = %1
kcos(kx) + c
%sin(!x)dx = % 1
!cos(!x) + c
%sin
#1
2x
$dx = %2 cos
#1
2x
$+ c
(12)
%cos(f(x))# f !(x)dx = sin(f(x)) + c
%cos(x2)# 2xdx = sin(x2) + c
%cos(x2+2x)#(2x+2)dx = sin(x2+2x)+c
%cos(5e7x)#35e7xdx = sin(5e7x) + c
(13)
%sin(f(x))# f !(x) dx = % cos(f(x)) + c
%sin(x2)# 2x dx = % cos(x2) + c
%cos(x2)# 2x dx = sin(x2) + c
%sin(%x3)#(%3x2)dx = % cos(%x3)+c
%sin(ln(x))#1
xdx = % cos(ln(x)) + c
Draft Version August 2011 c!2010 University of Sydney 39
3.6 Solving Di!erential Equations of the Formdy
dx= f(y)
For a di!erential equation of the formdy
dx= f(x),
if we can integrate f(x) we can simple integrate both sides of the equation to find y(x). For such equations see
the section Solving Di!erential Equation of the Formdy
dx= f(x) Using Integration.
Alternatively, if the right hand side of the di!erential equation involves y, as we are considering here, thedi!erential equation is asking essentially quite a di!erent question.
3.6.1 Di!erential Equation of the Formdy
dx= y
For instance, the di!erential equation:dy
dx= y
is asking the question:
Can you think of a function y, which is a function of x, such that if we di!erentiate that functionwe get back the the function we first thought of?
In other words,dy
dx= y is asking what function is the same function when you di!erentiate it.
One answer is y = ex since
d
dxy =
d
dxex = ex = y = the original function.
The function y(x) = ex is a special function because it is, its own derivative.
But there are others.
What about y = 2ex. Using the di!erentiation rules;
d
dxy =
d
dx2ex = 2
d
dxex = 2ex = y = the original function.
So y = 2ex is also its own derivative. In fact any function of the form y = Aex, where A is a constant, will havea derivative equal to the function we first started with as;
d
dxy =
d
dxAex = A
d
dxex = Aex = y = the original function.
In fact a constant times the exponential function are the only functions with this property.
The functions y(x) = Aex, where A is a constant, are the only functions that are their own derivatives.
So y(x) = Aex is the general solution to the di!erential equationdy
dx= y.
Draft Version August 2011 c!2010 University of Sydney 40
3.6.2 Exercises
1. Write down three particular solutions for the di!erential equation
dy
dx= y
2. Write down a sentence in words that describes what the following di!erential equation is asking in math-ematics
dX
dt= X
3. Write down three particular solutions to the di!erential equation and hence the equivalent worded questionin Question 2.
4. Use your answers to Question 3 to write down a general solution to the di!erential equation on Question 2.
5. Check your general solution in Question 4 by substituting your answer into the di!erential equation
dX
dt= X
6. Write down three particular solutions and the general solution to
Z !(y) = Z(y)
Draft Version August 2011 c!2010 University of Sydney 41
3.6.3 Di!erential Equation of the Formdy
dx= ky
The di!erential equationdy
dx= 2y is asking the question:
What function y when you di!erentiate it gives twice the original function?
Such a function is y(x) = e2x. Since
d
dxy =
d
dxe2x = 2e2x = 2# y = twice the original function.
Another function that satisfies this is y = 10e2x. Here
d
dxy =
d
dx10e2x = 10
d
dxe2x = 10# 2e2x = 2# 10e2x = 2# y = twice the original function.
That is, y = 10e2x a function, such that when we di!erentiate it, we get back two times the function we firststarted with.
In fact any function of the form y(x) = Ae2x will have the derivative equal to twice the function we first started
with. And these are the only functions wheredy
dx= 2y. Hence
The functions y(x) = Ae2x, where A is a constant, are the only function with their derivatives equalto twice the original functions.
Indeed if we di!erentiate y = ekx, the derivative will be k times the original function;
d
dxy =
d
dxekx =
d
dxekx = k # ekx = k # y = k times the original function.
And finally any function of the form y(x) = Aekx will have its derivative equal to k times the original function;
d
dxy =
d
dxAekx = A
d
dxekx = Ak # ekx = k #Aekx = k # y = k times the original function.
The functions y(x) = Aekx, where A is a constant, are the only function, such that their derivativesare k times the original function.
So y(x) = Aekx is the general solution to the di!erential equationdy
dx= ky.
Example
Find the general solution of the di!erential equationdy
dx= 15y.
Here we want a function who’s derivative is 15 times the original function. Such a function is y(x) = e15x. Soy(x) = e15x is just one particular solution to the di!erential equation. But this is not the only function thathas its derivative equal to 15 times y. Any function of the form y = Ae15x will have its derivative equal to 15times the original function. And since we are asked for the general solution we need to give the most generalanswer.
So y(x) = Ae15x is the general solution of the di!erential equationdy
dx= 15y.
Obviously we could just remember a formula for the general solution to this di!erential equation but it is farmore important to understand why something is a general solution, and what this means.
dy
dx= 15y is a di!erential equation.
y(x) = e15x is just one particular solution to the di!erential equationdy
dx= 15y.
y(x) = Ae15x, where A is a constant, is the general solution to the di!erential equationdy
dx= 15y.
Draft Version August 2011 c!2010 University of Sydney 42
3.6.4 Exercises
For the following questions the di!erentiation tables may be useful.
1. Which function when you di!erentiate it gives twice the original function?
(a) y = ex
(b) y = 2e2x
(c) y = e2t
(d) X = 2e2t
(e) none of the above.
2. Which of the functions answers the question:
Which function y when you di!erentiate it gives negative the original function?
(a) y = ex
(b) y = %ex
(c) y = e"t
(d) X = %e"t
(e) none of the above.
3. Match up each of the questions with its di!erential equation.
For this question you need to know/remember that the second derivative of y with respect to x is given
byd2y
dx2. Likewise, by extension, the fourth derivative of y with respect to x is given by
d4y
dx4.
(a) Which function, when you di!erentiate it gives the same function?
(b) Which function has a derivative which is twice the original function?
(c) Which function is 5 times its derivative?
(d) Which function is one fifth times its derivative?
(e) Which function, when you di!erentiate it twice, gives minus the original function?
(f) Which function, when you di!erentiate it 4 times, gives back the original function?
(i)d2y
dx2= %y
(ii)d4y
dx4= y
(iii)dy
dx= 5y
(iv)dy
dx= y
(v)dy
dx= 2y
(vi)dy
dx=
1
5y
Draft Version August 2011 c!2010 University of Sydney 43
4. Match each question written in words labelled (a) to (f) to its di!erential equation labelled (i) to (vi).
(a) Which function, when you di!erentiate gives five times the original function?
(b) Which function, when you di!erentiate it give negative two times the original function?
(c) Which function when you di!erentiate it and add the original function gives you zero?
(d) Which function when you di!erentiate it and add three times the original function gives you zero?
(e) Which function when you di!erentiate it and subtract ! times the original function gives you zero?
(f) Which function when you di!erentiate it and add it to ! times the original function gives you zero?
(i)dy
dx= %3y
(ii)dy
dx= %2y
(iii)dy
dx= %y
(iv)dy
dx= %!y
(v)dy
dx= 5y
(vi)dy
dx= !y
Draft Version August 2011 c!2010 University of Sydney 44
3.6.5 How Not to Solve a Di!erential Equation of the Formdy
dx= f(y)
If the di!erential equation is of the formdy
dx= f(x) and we can integrate f(x) then we can find a solution by
simply integrating both sides of the equation.
If, on the other hand, the di!erential equation has a function of y on the right hand side we can’t just integrate.
If the di!erential equation is of the formdy
dx= f(y) we can not just integrate both sides of the
equation to find the solution.
Example (of why we cant just integrate both sides ofdy
dx= f(y) )
Lets say we havedy
dx= y.
We know that the general solution to this equation is y(x) = Aex.
We can try to integrate both sides of this equation with respect to x,
You must always integrate both sides of the equation with respect to the same variable.
which will give, %dy
dxdx =
%y dx.
A common mistake is then to incorrectly integrate the right hand side to give y # x+ c.
But we can not integrate y with respect to x unless we know what y is, in terms of x.
For instance if we knew that y(x) = Aex then we could happily substitute this into the equation to give;%
dy
dxdx =
%y dx =
%Aex dx = Aex + c giving y = Aex + c.
For c = 0 this does give us the correct answer y(x) = Aex, which is it’s own derivative. But sadly we have toknow the original solution beforehand in order to solve the di!erential equation using this method.
We also note here that another, perhaps less common, mistake is to simplify the integral
%y dx by incorrectly
integrating with respect to y instead of x. That is we should not integrate
%y dx to get
y2
2. Here we see that
the dx is indeed very important in an integral.
The dx in the integral is called the di!erential and determines what the we are integrating with respect to.
The dx in an integral such as
%f(x) dx is called the di!erential.
The di!erential dx determines what we are integrating with respect to; in this case x.
Here we see how important the di!erential is in an integral. For instance the integral
%y(x) dx cannot be
performed unless we know y(x), that is y as a function of x. On the other hand
%y dy can be found to be
y2
2as here we are integrating with respect to y.
The di!erential such as dx should never ever, ever be left o! of an integral.
Initially these can be common mistakes in solving equations that involvedy
dxand y. If these errors could be
eliminated from many students exams these students would score more highly.
To solve the type of di!erential equation (dy
dx= f(y)) you can try to use the method of separation of variables.
Chapter 4
Modelling and Calculus 4 MAC 4Relating written word descriptions ofreal world physical conditions to thedescription of the problem in thelanguage of mathematics and usingthese descriptions to find solutions tothe physical problem.
4.1 Finding Conditions in Questions
Often the environment and history of a problem will help to find a solution.
And so when a question is asked in words or mathematics we may have to interpret that question, and thewords and mathematics, into mathematics that we can use to find a solution.
There are a number of ways that a question can give us information about the physical situation or ask us foran answer. Some of these are:
Type 1 Initial Condition The question may state certain conditions that have existed in the past, or at thebeginning of the problem.
Type 2 Boundary Condition The question may tell us that one physical quantity has a value when anotherphysical quantity has another value.
Type 3 Condition of Rate at a given time The question may tell us the value of a rate of change at acertain time.
Type 4 Condition of Rate The question may tell us the value of a rate of change when another physicalquantity has another value.
Type 5 The question may ask us to find a physical quantity at a given time.
Type 6 The question may ask us to find a physical quantity when another quantity has a certain value.
Type 7 Common Sense Conditions We need to use some of our real world experience to place conditionson the variables. We don’t want volumes or distances to take negative values. Or we may not want ananswer of 3.14 people in a population.
45
Draft Version August 2011 c!2010 University of Sydney 46
Example 1
Question
A diving pool is the shape of a cube. This diving pool is drained for maintenance. The height of the water isgiven by H in metres. The pool drains at a rate proportional to H + c, where c is constant. Here then thedi!erential equation is given by;
dH
dt= %kH +A,
where t is time measured in hours. The constant of proportionality is %k and A = %kc. Why are the constantschosen in this way? Initially the water in the pool is 3 metres. After one hour the height of the water hasdroped to 2.5 metres. After two hours the height of the water is changing at a rate of 0.5 metres per hour.
1. Find the height of the water after three hours.
2. Find the time that it takes for all the water to drain out of the pool.
Answer
For this question the height of the water is changing with time. The height of the water H is the dependentvariable; the height is the solution function. The time, in hours, is the independent variable. We want to findH as a function of t.
The sentence
“ Initially the water in the pool is 3 metres.”
tells us what H was at the beginning. If we take t = 0 when the pool starts to drain then initially means att = 0.
If we take time t equals zero at the beginning of the process then initially means t = 0.
This is called an initial condition and it is a condition of Type 1 above.
The sentence
“ After one hour the height of the water has droped to 2.5 metres.”
tells us the height after one hour; it tells us H = 2.5 at or when t = 1.
The words after or at or when may tell us the value of one quantity when anotherquantity has another value.
This is sometimes called a boundary condition and it is a condition of Type 2 above.
The sentence
“ After two hours the height of the water is changing at a rate of 0.5 metres per hour.”
tells us the rate of change of the height after two hours. This tells usdH
dt= 0.5 at t = 2.
The combination of words rate or rate of change together with after or at or when may tell us the derivativeat a time t
The words rate or rate of change together with after or at or when may tell usdy
dtat t = something.
Draft Version August 2011 c!2010 University of Sydney 47
This is a condition of rate and it is a condition of Type 3 above.
If the question said:
“ The height of the water was changing at a rate of 0.5 metres per hour when the water was2 metres high.”
This is telling us the rate of change of one quantity when the quantity has a given value. HeredH
dt= 0.5 when
H = 2.
The words rate or rate of change together with when may tell usdy
dtat y = something.
This is a condition of type 4.
The question asks us to:
“ Find the height of the water after three hours.”
Which is asking us to find H when t = 3.
This is a question of Type 5 above.
The question also asks us to:
“ Find the time that it takes for all the water to drain out of the pool.”
Which is asking us to find the time t when the pool has emptied, that is when H = 0.
This is a question of Type 6 above.
Example 2
Question
A partially full swimming pool is being filled by a water source, where the rate at which the water is enteringthe pool is decreasing with time. The height H in metres of water in the pool is given by;
dH
dt= k
&t,
where t is the time in hours after 11:00 am on a Thursday. If the pool initially satisfied H(0) = 1.5 and laterthe pool is filling at a rate given by H !(4) = 6.
Find
1. The constant of integration.
2. The constant of proportionality.
3. H(4).
4. H !(9).
Draft Version August 2011 c!2010 University of Sydney 48
Answer
For this question again the height of the water is changing with time. The height of the waterH is the dependentvariable; the height is the solution function. The time, in hours, is the independent variable. We want to findH as a function of t.
We are told the di!erential equationdH
dt= k
&t. This equation is in the form
dy
dx= f(x) and we can simply
integrate both sides with respect to t.
You must always integrate both sides of the equation with respect to the same variable.
%dH
dtdt =
%k&tdt = k
% &tdt = k
%t1/2dt.
So the general solution of the di!erential equation is
H(t) = kt3/2
3/2+ c = k
2
3t3/2 + c
The statement
“ the pool initially satisfied H(0) = 1.5”
tells us what H was at the beginning. This time the question gives us the initial height as an equation. Ifwe take t = 0 when the pool starts to fill then initially means at t = 0. Here the initial height is given as anequation. H(0) = 1.5 means that when the independent variable, here t, is zero then H is 1.5. Another way ofwriting this equation is H(t = 0) = 1.5. Yet another way is to simply say when t = 0 H = 1.5. You need toknow all these forms of expressing a condition.
In general, for a function y(x), the statement y(a) = b means that when x = a then y = b.
This is called an initial condition and it is a condition of Type 1 above.
We can use this initial condition H(0) = 1.5 to find the constant of integration. Substituting into the di!erential
equation we get 1.5 = k2
3t3/2 + c = c. Hence the constant of integration c = 1.5.
The answer to part 1 of the question is then: The constant of integration is 1.5
The general solution is then H(t) = k2
3t3/2 + 1.5
The statement
“ later the pool is filling at a rate given by H !(4) = 6”
tells us H ! at a given time. This time the question gives us the rate of change of height as an equation. Theequation H !(4) = 6 tells us that at t = 4, H !(t) = 6 or at t = 4, H ! = 6. Another way of writing this is to say
that at t = 4 we havedH
dt= 6. This is telling us that after 4 hours the rate at of change of height of the water
in the pool is 6 metres per hour. You need to know all these forms of expressing this condition.
In general, for a function y(x), the statement y!(a) = b means that when x = a then y!(x) = b.
Draft Version August 2011 c!2010 University of Sydney 49
This is called a condition of rate and it is a condition of Type 3 above.
Since this condition tells us something about the rate of change of H or H !, to use this condition we need tofirstly find an equation for H !. Di!erentiating the general solution for H gives
dH
dt=
d
dt
#k2
3t3/2 + 1.5
$= k
2
3
3
2t3/2"1 = k t1/2.
A much easier way of finding the derivative is to simply use the di!erential equation.dH
dt= k
&t.
Substituting t = 4 into our equation for the derivative gives H !(4) = k&4 = 6. Dividing both sides of this
equation by 2 gives k = 3
The answer to part 2 of the question is then: The constant of proportionality is 3.
Substituting for k gives the general solution as H(t) = 32
3t3/2 + 1.5 = 2 t3/2 + 1.5.
Part 3 of the question is asking for H(4) which is asking us to evaluate H at t = 4. To do this we simplysubstitute t = 4 into our general solution. Giving
H(t = 4) = H(4) = 2# 43/2 + 1.5 = 2# 8 + 1.5 = 17.5.
The answer to part 3 is H(4) = 17.5
Part 4 of the question is asking for H !(9) which is asking us to evaluate H !(t) at t = 9, that isdH
dtat t = 9. To
do this we need to find the derivative of H. To do this we could di!erentiate H(t) viz.;
dH
dt=
d
dt
'2 t3/2 + 1.5
(= 3 t1/2 = 3
&t.
Alternatively we can simply use the di!erential equation: The di!erential equation is
dH
dt= k
&t substituting for k gives = 3
&t
This gives us the derivative directly, without solving the di!erential equation by integration and then di!eren-tiating it again.
To find H !(9) then we simply substitute t = 9 into our our formula fordH
dt. Giving
dH
dt t=9= H !(9) = 3
&9 = 3# 3 = 9
The answer to part 4 is H !(9) = 9.
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4.1.1 Exercises
For the following questions, a set of conditions are given in words and mathematics.
For each part (a), (b), (c). . . write the condition as a set of mathematical equations (for example when t = 0H = 15).
Note for these questions you do not need to find the constant of integration (c say) or the constant of propor-tionality (k say).
Note also that each part (a), (b), (c). . . may give you a di!erent value for the constant of integration and/orconstant of proportionality.
1. During a period of no rain the height H of a river, in metres, drops according to the equation;
dH
dt= %0.15H,
where t is measured in hours after the rain stops.
(a) Initially the height of the river is 15 metres.
(b) One hour after the rain stops the height of the river is 13.5 metres.
(c) When the rain first stops falling the height of the river is 24 metres.
(d) Two days after the rain first stops falling the height of the river is 12.7 metres.
(e) At the time when the rain stops falling the height is 1550 mm.
(f) Three days after the rain first stops falling the height of the river is 2440 mm.
(g) H(24) = 7.
(h) H(0) = 15.3.
Note: Only one of these conditions will be needed to find the constant of integration in the general solutionand thus find the particular solution.
2. The amount of medication in a patients body M , measured in milligrams, is given by the di!erentialequation;
dM
dt= %kM,
where t is the time after the medication is administered, measured in minutes, and k is a constant.
(a) 150 milligrams of medication are administered.
(b) 150 minutes after the medication is given the amount in the blood is 45 mg
(c) Initially 250 milligrams of medication are given.
(d) Two days after the medication is given the amount in the blood is 17 mg.
(e) The rate of change of medication in the body is 12 mg/min when the amount of medication is 175mg.
(f) Five hours after the medication is administered the rate of change of medication is 2 mg/min.
(g) One hour after the medication is given the rate of change of medication is given by 12.5 mg/min.
(h) M(0) = 15.3.
(i) M !(60) = 3.
(j) M !(360) = 3.5.
(k) M(60) = 145.
Note: You may need only two such conditions to find the constant of proportionality k, and the constantof integration in the general solution and thus find the particular solution.
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3. The number of fish in a fishery holding pond, will increase at a rate proportional to the number of fish inthe holding pond. The larger the population the quicker the fish will bread. This population is also beingused as source of food such that fish are being removed at a constant cull rate R say. The number of fishin the population P measured in thousands of fish will be governed by the di!erential equation;
dP
dt= kP %R,
where t is the time after the holding pond is first established, measured in hours, and k is the reproductionrate constant.
(a) Initially the holding pond is stocked with 2.34 thousand fish.
(b) 3.5 hours after the holding pond is first established the fish population is 1324 fish.
(c) Initially the rate of change of fish in the population will be 2000 fish per hour.
(d) Two days after the holding pond is first established the fish population is decreasing at a rate of 0.524thousand fish per hour.
(e) The rate of at which fish are being removed from the pond is (a constant) 500 fish per hour.
(f) 24 days 6 hours after establishing the holding pond there are no fish left.
(g) One day after establishment there are 22564 fish in the holding pond.
(h) P (24) = 1000.
(i) P !(0) = 2.
(j) P !(24) = 2.0.
(k) P (150) = 0.
Note: You may need only three such conditions to find; the production rate constant k, the cull rateconstant R, and the constant of integration to find the particular solution from the general solution.
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4.2 Ten Important Steps for Solving Modelling Questions Posed inWords
Here we work through an example showing how to identify the important information in the question or problem.We identify the key words or phrases in the question that provide us with information about the model and keywords that provide us with information about physical environment, information about what has happened inthe past, and what is being asked in the question.
We also identify important steps in the solution of the problem and provide guidelines for how the solutionshould be set out; including the wording that should be used in your solution.
There are other ways to solve every problem and the solution provided is just an example of how the answermay be set out.
Many answers to modeling and calculus problems will use some or all of the steps shown. Many answers tothese modeling problems will use the steps shown and many more. They are a good place to start when learningmodelling and di!erential equations.
Example
A hot pie is taken straight from the microwave, and put in a cold room that is at zero degrees Celsius.
The pie cools at a rate proportional to the temperature of the pie.
If the pie is initially at 86#C and takes 152 minutes to cool to half the temperature (in #C )
(i) Find the general solution to this problem.
(ii) Find the particular solution to this problem.
(iii) What temperature will the pie be after 10 hours?
(iv) How long does it take for the pie to be edible at 23#C or below?
This example has 10 important steps for solving a modelling question.
Step 1 Identify the variables in the question and give them names and units.
(a) From the question identify what will change.
Here the temperature is changing as time changes.
(b) Give this a name or symbol.
Let the temperature of the pie be T .
(c) Decide what this is measured in.
T is measures in #C (from the question).
(d) What does T change with?
Temperature changes over time.
(e) Decide what this is measured in?
Time is measured in minutes (from the question).
Here T is the dependent variable. We want to find the temperature as a function of time. So T is thesolution function and t is the independent variable.
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We want to find T (Temperature in #C) as a function of t (in minutes).We want T = T (t).
Step 2 From the question use the wording to put together a di!erential equation for T and t.
From the question Rate here meansd
dt
The rate of change of temperature will bedT
dtIf the rate is proportional to the temperature then
dT
dt" T or
dT
dt= KT,
where K is some constant.
Now, as indicated in the question, the pie cools at a rate proportional to the temperature of thepie. This means that the temperature of the pie will decrease quicker the hotter the pie is.If the pie is cooling then the rate of change of T will be negative.Really hot pies’ temperatures will decrease quickly. Pies that are just a little warm will still cool down
but their temperature will decrease more slowly. Really hot pies will have a large negativedT
dtWarm pies
will still have a negativedT
dtbut this will be less negative, indicating the temperature is still decreasing
but less rapidly.
Since the pie is cooling the temperature will be decreasing sodT
dtwill be negative. So we have:
dT
dt= % kT,
where k here will be a positive constant (k = %K).
k is the constant of proportionality.
k should not be confused with the constant of integration that is will be introduced when we integratethe di!erential equation.
The di!erential equation is thendT
dt= % kT
We note here that if the room was not at a constant temperature of 0#C then the pie would cool at arate proportional to the di!erence between the temperature of the pie and the room.
If TRoom is the temperature of the room (held constant) then the di!erentialequation for Newton law of cooling is
dT
dt= % k(T % TRoom)
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Step 3 Pose the di!erential equation as a mathematical question in words.This step can help understand what the problem is asking and what the di!erential equation represents
The di!erential equation isdT
dt= %kT
The di!erential equation is asking
Can you think of a function T which is a function of t such that when you di!erentiate thatfunction you get k times the original function?
Step 4 Find the general solution of the di!erential equation.
Use your knowledge of; di!erentiation backwards (anti-di!erentiation), or integration, or separation ofvariables, or another technique to solve the di!erential equation.
The function y(x) = e"kx has derivatived
dxy =
d
dxe"kx = %ke"kx = %k # e"kx = %k # y(x).
So we know that the derivative of this function is %k times the original function, and hence the functionwill solve the di!erential equation.
So T (t) = e"kt is a solution to the di!erential equation.
In general any function T (t) = Ae"kt, where A is a constant, will solve the di!erential equationdT
dt= %kT .
Hence T (t) = Ae"kt is the general solution to the di!erential equation.
Hence T (t) = Ae"kt is the general solution to the di!erential equation.
Dont get the constants mixed up here
k is the constant of proportionality.It comes from constructing the di!erential equation from the question.
A is the constant of integration.It comes from integrating, or using anti-di!erentiation to find the general
solution of the di!erential equation.
This answers part (i) of the question.
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Step 5 From the question, pick out any information in words that will allow you to find the constants in ourgeneral solution.
The general solutionT (t) = Ae"kt
has two constants (k and A), and we will need two sets of conditions from the question to find them.
The question says
“The pie is initially at 86#C”.
Here initial means when we start to measure time.
So this tells us that at t = 0, T = 86.
The question also says
“. . . and takes 152 minutes to cool to half the temperature”.
So after 152 minutes the temperature will be 43#C or T = 43.So at t = 152, T = 43.
At t = 0 T = 86 is called an initial condition.
At t = 152, T = 43 is sometimes called a boundary condition.
Step 6 Use the boundary and initial conditions from the question to find a particular solution.
Substitute t = 0 and T = 86 into T (t) = Ae"kt gives:
86 = Ce"k$0 = Ae0 = A# 1 = A
Hence A = 86.
We then substitute this value of A back into our general solution to find the particular solution.
You must substitute the value of the constant of integration back into thegeneral solution to find the particular solution.
State the particular solution
The particular solution is then T (t) = 86e"kt.
This answers part (ii) of the question.
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Step 7 Use the condition in the question to find the constant of proportionality.
We now use the second condition to find k.Substituting t = 152 and T = 43 into the particular solution. We get
T (152) = 43 = 86e"k$152.
To find k we:
÷ both sides by 8643
86= e"k$152
To get k out of the power take ln of both sides ln
#43
86
$= ln
)e"k$152
*= %k # 152
÷ both sides by %1521
%152ln
#43
86
$=
%k # 152
%152= k
Work out the value of k on the calculator k ' 0.00456
Substitute this k = 0.00456 into the particular solution T = e"kt, and state the answer.
The particular solution for the conditions described in the problem is
T (t) = 86e"0.00456t
This answers part (ii) of the question with the constant of proportionality evaluated.
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Step 8 From the wording of the question work out what the question is asking in mathematics.
Part (iii) of the question asks:
What will be the temperature of the pie after 10 hours?
Since we are using t measured in minutes we must change 10 hours to minutes.To do this we use the unit conversion factor. Here we want to convert hours to minutes, and we know
1 hour is equivalent to 60 minutes. So here our unit conversion factor is60minute
1 hour.
To change the units of a quantity from unit1 to unit2, where we know that A unit1 is equivalentto B unit2 we multiply by the unit conversion factor given by;
unit conversion factor =B Unit2A Unit1
Examples
The unit conversion factor for converting minutes into hours1 hour
60minute
The unit conversion factor for converting metres into kilometres is1 kilometre
1000metre
The unit conversion factor for converting degrees into radians is2! radian
360 degree
The unit conversion factor for converting radians into degrees is360 degree
2! radian.
The length of time 60 minutes is equivalent to 1 hour so our unit conversion factor60minutes
1 houris equal
to 1. As an equation;
unit conversion factor =60minutes
1 hour= 1
Hence if we multiply any quantity by the appropriate unit conversion factor this is equivalent tomultiplying that quantity by unity. As we know multiplying a quantity by unity does not change theamount of that quantity.
Multiplying a quantity by the appropriate unit conversion factor does not change the amountof the quantity under consideration only the units in which the quantity is expressed.
In this instance to express our 10 hours in minutes we have;
10 hour = 10 hour# 60minute
1 hour= 600minute.
Be careful to change all units to the units of the variables here T and t.
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Step 9 Calculate the answer in mathematics.
Substituting t = 600 into T (t) = 86e"0.00456$t
gives
T = 86e"0.00456$600
= 86e"2.736
= 86# 0.064829
= 5.5753
Step 10 State the answer in words including units.
If you just give T = 5.5753 this provides little information who doesn’t know all of your working.
Is this the temperature or does T mean time? It could mean after 5.57 hours to an outsider.
State the answer in words including units.
The pie will cool to 5.5753#C after 10 hours.
This answers part (iii) of the question.
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We now answer part (iv) of the question. To do this we work through Step 8, Step 9 and Step 10 again aswe did for part for part (iii).
Step 8 for part (iv) From the wording of the question work out what the question is asking in mathematics.
Part (iv) of the question asks:
How long does it take for the pie to be edible at 23#C or below?
Since we are measuring time from t = 0 when the pie is taken from the oven. We want to find the time t(in minutes) when the temperature T had dropped to 23#C (which is already in #C).
We want t when T = 23.
Always check the units when information is given in the question andwhen you are stating an answer.
Step 9 Calculate the answer in mathematics.
Substituting T = 23 into T (t) = 86e"0.00456$t
gives
23 = 86e"0.00456$t
We need to get t on its own. To do this we:
÷ both sides by 8623
86= e"0.00456$t
To get t out of the power take ln of both sides ln
#23
86
$= ln
)e"0.00456$t
*= %0.00456# t
÷ both sides by %0.004561
%0.00456ln
#23
86
$=
%1.318853
%0.00456= t
Work out the value of t on the calculator t ' 289.22
Step 10 State the answer in words including units.
Giving the answer in words allows someone who is unfamiliar with your choice of symbols or units tounderstand your answer.T , t, x or y means little to someone who doesn’t know the mathematics. Also an outsider will not knowwhich units you have chosen.
State the answer in words including units.
The time for the pie to cool to 23#C is 289.22 minutes.
This answers part (iv) of the question.
Chapter 5
Answers to Selected Exercises
5.1 Answers to Exercises 1.1.2
Question 1
The rate of increase of temperature of the sausage may be represented bydT
dt, where T is the temperature of
the sausage.
Question 2
The rate of change of concentration of salt may be represented bydS
dt, where S is the concentration of salt.
Question 3
The rate at which a human body produces insulin may be represented bydI
dt, where I is the insulin in the body.
Question 4
The rate at which fuel is taken from the fuel tank and fed into the engine may be represented bydF
dtwhere F
is the total volume of fuel being taken from the fuel tank and fed to the engine.
If the same amount of fuel is being fed to the engine per unit time the car will stay traveling at the same speed;
that is ifdF
dtis constant then the speed of the car will remain the same.
Here there is another rate in the question. How fast the car is traveling may be represented by the rate at which
the car changes its distance along a road; which may be represented bydD
dt, where D represents the distance
of the car along the road.
Question 5
The rate at whichdF
dtchanges will then be represented by
d
dt
dF
dt.
If the rate at which fuel is fed into the engine is simply represented by R then the rate of change of the rate at
which fuel is fed to the engine will be represented bydR
dt.
The acceleration of the car is also represented by a derivative, it is the rate of change of velocity. So acceleration
is given bydv
dt, where here the velocity v is the velocity along a straight road. More generally velocity in any
direction is written as a vector v though here we will stick with scalar quantities.
Even the velocity is a derivative. The velocity v here is the rate of change of displacement along a (here) straight
road. And is written asdD
dtin the language of mathematics, where D is the distance along the straight road.
Question 6
60
Draft Version August 2011 c!2010 University of Sydney 61
The rate at which the depth of water drops in the pool may be represented bydD
dt, where D represents the
depth of water in the swimming pool. If the rate at which the depth of water drops is dependent on the depth
of water thendD
dtwill depend on D. Another way of saying this is that
dD
dtwill be some function of D. Or
dD
dt= f(D); but more about this in the next section.
Question 7
The rate of change of the volume of the balloon may be represented in the language of mathematics asdV
dtthis mathematical expression represents the rate of change of a quantity and the quantity itself will be V thevolume of the balloon. If the rate of decrease of volume of the balloon is dependent on the diameter D say then
we can write in mathematicsdV
dt= f(D). But again we will explain this more thoroughly in the next section.
5.2 Answers to Exercises 1.2.3
Question 1
the rate of change of volume of the balloon is the derivativedV
dt.
the of volume of the balloon is the quantity V .
is equal to represents the equality or =.
2000 litres per minute tells us the rate of change.
The di!erential equation may be given bydV
dt= 2000 you do not have to give this to answer the question.
Question 2
The rate of change of temperature of a cold beer is the derivativedT
dt.
the temperature of a cold beer is the quantity T .
is equal to represents the equality or =.
the di!erence in temperature of the room and the beer tells us the rate of change.
The di!erential equation may be given bydT
dt= R % B you do not have to give this to answer the
question.
Question 3
The rate at which a swimming pool is filled is the derivativedV
dt.
the volume of water in the pool is the quantity V .
is equal to represents the equality or =.
a constant times the opening in the tap tells us the rate of change.
The di!erential equation may be given bydV
dt= constant # Openingtap you do not have to give this to
answer the question.
Question 4
the rate of change of the speed is the derivativedv
dt.
the speed of the bowling ball (downwards) is the quantity v.
is increasing by represents the equality or =.
9.8 metres per second every second tells us the rate of change.
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The di!erential equation may be given bydv
dt= 9.8 you do not have to give this to answer the question.
Question 5
the rate of change of volume of the balloon is the derivativedV
dt.
the volume of the balloon is the quantity V .
is equal to represents the equality or =.
a constant times the volume of the balloon tells us the rate of change.
The di!erential equation may be given bydV
dt= constant# V , here the constant will be negative you do not
have to give this to answer the question.
Question 6
The rate of change of concentration of alcohol in the blood stream of a person is the derivativedC
dt.
the concentration of alcohol in the blood stream of a person is the quantity C.
is constant tells us about the equality = (as well as other things).
is constant also tells us the rate of change.
The di!erential equation may be given bydC
dt= constant, here the constant will be negative as C decreases
you do not have to give this to answer the question.
Question 7
The change of speed of an object falling to Earth will increase at a constant rate is another way of
describing the derivativedS
dt.
the speed of an object falling to Earth (taken as downwards) is the quantity S.
will increase at a constant rate tells us about the equality = (as well as other things).
will increase at a constant rate also tells us the rate of change.
The di!erential equation may be given bydS
dt= 9.8, you do not have to give this to answer the question.
Question 8
The rate of change of the wind-speed describes the derivativedw
dt.
the the wind-speed (where the wind-speed is positive if it is onshore and negative if is or o!shore)is the quantity w.
will be dependent on tells us about the equality = (as well as other things).
the di!erence in the temperature of the land and the ocean tells us the rate of change.
The di!erential equation may be given bydw
dt= f(Tland % Tocean), here the constant will be negative as C
decreases you do not have to give this to answer the question.
Question 9
the rate at which a small shark population increases describes the derivative as well as other thing
(increases)dP
dt.
shark population is the quantity P .
will equal tells us about the equality =.
a constant times the number of fish in their habitat tells us the rate of change.
The di!erential equation may be given bydP
dt= constant # F , here the constant will be positive as P will
increase the larger F you do not have to give this to answer the question.
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5.3 Answers to Exercises 1.3.2
Question 1
Yes, diameter = 2# radius
Question 2
Yes, circumference = ! # diameter
Question 3
Yes, circumference = ! # diameter
Question 4
Yes, perimeter = 4# side-length
Question 5
No, area = side-length2 = 1 # side-length2. There is a constant 1 in the equation but the squared ( 2) in theequation means the two quantities are not proportional.
Question 6
No, area = ! # radius2. Even though there is the constant ! in the equation the squared ( 2) in the equationmeans the two quantities are not proportional.
Question 7
Generally the height of a person and the weight of a person are not proportional. Even though a taller personmay be heavier and a short person on average will be lighter there is no hard and fast single equation whichrelates the heigh and weight of people. If these two quantities were always proportional we could predict theweight of a person from their height, which in general we cannot.
Question 8
Again, generally speaking the size of a class will not determine how many people pass that class. If there is avery good year in a class with many hardworking students then a larger proportion should pass that class.
Question 9
Yes, area = ! # radius2. Note here the area and radius2 are related only the constant !.
Question 10
The side length of a cube s that (just) contains a sphere of radius r will be s = 2#&3r. So the volume of the
sphere Vsphere will be Vsphere =4
3!r3 and the volume of the cube Vcube will be Vcube = (2
&3r)3 = 8# 3
&3r3.
Hence
Vcube = 24&3r3 = 24
&33
4!
4
3!r3 = 24
&33
4!Vsphere =
18&3
!Vsphere.
So the volumes of the cube and the sphere are related by Vcube =18
&3
!Vsphere so they are indeed proportional.
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5.4 Answers to Exercises 1.3.4
Question 1
radius =1
2diameter, so the constant of proportionality is
1
2.
Question 2
diameter =1
!circumference, so the constant of proportionality is
1
!.
Question 3
side-length =1
4perimeter, so the constant of proportionality is
1
4.
Question 4
radius =1
2!circumference, so the constant of proportionality is
1
2!.
Question 5
volumecube = 1# side-length3, so the constant of proportionality is 1.
Question 6
volumesphere =4
3!radius3, so the constant of proportionality is
4
3!.
Question 7
An inch is defined to be inch = 24.5millimetre exactly, so the constant of proportionality is 24.5.
Question 8
A litre is defined to be 100 mm cubed. That is it is the volume contained in a cube that is 10 cms by 10 cmsby 10 cms.This means there are 10# 10# 10 litres in a cubic metre.
In other words 1000 litres = 1cubic metre or 1 litres =1
1000cubic metre, so the constant of proportionality is
0.001.
Question 9
side-length =1&2diagonal, so the constant of proportionality is
1&2.
Question 10
areacircle = !radius2 and areasquare = (2radius)2. Hence areasquare =4
!areacircle, so the constant of proportionality
is4
!.
Question 11
The side length of a cube s that (just) contains a sphere of radius r will be s = 2#&3r. So the volume of the
sphere Vsphere will be Vsphere =4
3!r3 and the volume of the cube Vcube will be Vcube = (2
&3r)3 = 8# 3
&3r3.
Hence
Vcube = 24&3r3 = 24
&33
4!
4
3!r3 = 24
&33
4!Vsphere =
18&3
!Vsphere.
So the volumes of the cube and the sphere are related by Vcube =18&3
!Vsphere and the constant of proportionality
is18&3
!.
Question 12
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Many students would choose 100 % of the students to pass the class, if this were the case
no. of students passing the class = no. of students in the class.
So here the constant of proportionality would be 1.
Even if many students would choose all to pass, in order for “passing” the maths class to be worthy of somerecognition, many students may agree that just enrolling should not be su#cient to pass.
Question 13
If we choose only 10 % of students to fail a maths class then
no. of students failing the class =10
100no. of students in the class =
1
10no. of students in the class,
in this case the constant of proportionality would be 0.1.
If everyone passed the class then
no. of students failing the class = 0 = 0# no. of students failing the class.
We may be tempted to conclude that the constant of proportionality is 0. However the constant of propor-tionality is common defined to exclude 0. Under such a definition, in this case of everyone passing, the twoquantities would be determined to be not proportional.
Question 14
area = ! # radius2, so the constant of proportionality is !.
5.5 Answers to Exercises 2.1.4
Question 1
Solution function is y. The independent variable is x.
Question 2
Solution function is y. The independent variable is x.
Question 3
Solution function is y. The independent variable is x.
Question 4
Solution function is y. The independent variable is x.
Question 5
Solution function is x. The independent variable is y.
Question 6
Solution function is x. The independent variable is t.
Question 7
Solution function is x. The independent variable is t.
Question 8
Solution function is z. The independent variable is y.
Question 9
Solution function is z. The independent variable is x.
Question 10
There are two possible answers to this question.
Draft Version August 2011 c!2010 University of Sydney 66
As the equation stands or multiplying throughout bydy
dxto give 1 + 3y
dy
dx= 0 gives the solution function as y
and the independent variable is x.
Alternatively and just as correctly we could use the property that for well behaved functions y(x),1dy
dx
=dx
dy.
We can then rearrange the di!erential equation to bedx
dy+ 3y = 0 in which case the solution function is x and
the independent variable would be y.
Question 11
Solution functions are x and y. The independent variable is t.
Question 12
Solution function is X. The independent variable is t.
Question 13
Solution function is X. The independent variable is t.
Question 14
Solution function is X. The independent variable is t.
Question 15
Solution function is X. The independent variable is Z.
Question 16
Solution function is Y . The independent variable is Z.
Question 17
Solution function is X. The independent variable is t.
Question 18
Solution functions are X and Y . The independent variable is t.
Question 19
Solution function is X. The independent variable is t.
Question 20
Solution function is X. The independent variable is t.
5.6 Answers to Exercises 2.2.2
Question 1
Can you think of a function y, which is a function of x, such that when you di!erentiate that function you get2.
Question 2
Can you think of a function y, which is a function of x, such that when you di!erentiate that function you get2x.
Question 3
Can you think of a function y, which is a function of x, such that when you di!erentiate that function you getsin(x).
Question 4
Can you think of a function y, which is a function of x, such that when you di!erentiate that function you get3x2.
Draft Version August 2011 c!2010 University of Sydney 67
Question 5
Can you think of a function y, which is a function of x, such that when you di!erentiate that function you getex.
Question 6
Can you think of a function y, which is a function of x, such that when you di!erentiate that function you getx sin(x).
Question 7
Can you think of a function y, which is a function of x, such that when you di!erentiate that function and add2x you get 3.
Question 8
Can you think of a function X, which is a function of t, such that when you di!erentiate that function you get3t2.
Question 9
Can you think of a function Y , which is a function of z, such that when you di!erentiate that function you getsin(z) + z.
Question 10
Can you think of a function W , which is a function of t, such that when you di!erentiate that function and addsin(t) to it you get 15.
Question 11
Can you think of a function y, which is a function of x, such that when you di!erentiate that function and thenmultiply the derivative by x you get 3.
Question 12
Can you think of a function y, which is a function of x, such that when you di!erentiate that function and thenmultiply the derivative by sin(x) you get x sin(x).
Question 13
Can you think of a function y, which is a function of x, such that when you di!erentiate that function and thenmultiply the derivative by ex you get e2x.
Question 14
Can you think of a function y, which is a function of x, such that when you di!erentiate that function and thenmultiply the derivative by itself (that is square it) you get (3x2 + 2)2.
Question 15
Can you think of a function X, which is a function of t, such that when you di!erentiate that function and addthe function you get 3t2.
Question 16
Can you think of a function X, which is a function of t, such that when you di!erentiate that function and thenmultiply the derivative by itself (that is square it) and then add the derivative of the function you get 13.
Question 17
Can you think of a function y, which is a function of x, such that when you di!erentiate that function andthen multiply the derivative by itself (that is square it) and then multiply the square of the derivative by thefunction and then add sin(x) you get 0.
Question 18
Can you think of a function Z, which is a function of Y , such that when you di!erentiate that function andthen multiply the derivative by the function and then add 3 times the function you get Y 2.
Question 19
Can you think of a function y, which is a function of x, such that when you multiply the derivative of thatfunction by 2, add 3 times the function and then add sin(x) you get 0.
Question 20
Can you think of a function X, which is a function of t, such that when you di!erentiate that function and thenmultiply the derivative by itself (that is square it) and then add the function times sin(t) you get t2.
Draft Version August 2011 c!2010 University of Sydney 68
5.7 Answers to Exercises 2.2.5
Question 1 (e).
Question 2 (c).
Question 3 (d).
Question 4 (f).
Question 5 (a) represents (iii), (b) represents (v), (c) represents (i), (d) represents (ii), (e) represents (iv).
5.8 Answers to Exercises 2.3.2
Question 1 (a), (b), (c), (d).
Question 2 (a), (b).
Question 3 (c), (e). The answer (e) qualifies as a solution as; if d is a constant then 2d will also be a constant.The constant d in part (d) corresponds to c/2 in the general solution of part (c).
5.9 Answers to Exercises 2.3.4
Question 1 (a) (i), (b) (iii), (c) (ii), (d) (v), (e) (vi), (f) (ii).
Question 2 (a) (vi), (b) (i), (c) (ii), (d) (iv), (e) (iii), (f) (i).
Question 3 (a) matches none of the descriptions, (b) (ii), (c) matches none of the descriptions, (d) (i), (e) (iii),(f) (ii).
Question 4 (a) matches none of the descriptions, (b) (i), (c) (ii), (d) matches none of the descriptions, (e) (iii),(f) (ii).
5.10 Answers to Exercises 3.1.1
Question 1 (b), (d).
Question 2 (d).
Question 3 (a).
Question 4 (e).
Question 5 (c), (d).
Question 6 (d).
Question 7 (a), (b), (c).
Question 8 (c).
Question 9 (d).
Question 10 (a), (b), (c), (d).
Draft Version August 2011 c!2010 University of Sydney 69
5.11 Answers to Exercises 3.3.1
Question 1 y(x) =3
4x4 + c.
Question 2 y(x) = 2x+ c.
Question 3 y(x) =5
7x7 % 4x4 + c.
Question 4 y(x) =!
3x3 + c.
Question 5 y(x) = sin(x) + c.
Question 6 y(x) =1
5e5x + c.
Question 7 y(x) = x2 + sin(x) + c.
Question 8 y(x) =1
3sin(3x) + c.
Question 9 y(x) = sin(x2) + c.
Question 10 y(x) = ex2
+ c.
Question 11 y(x) = 5 ln(x)% cos(3x5) + c.
5.12 Answers to Exercises 3.4.1
Question 1
Left hand side of d.e. isd
dxy =
d
dx
#3
4x4
$
=3
4# 4x3
= 3x3
= Right hand side of d.e.
Which verifies that the function is a solution of the di!erential equation.
Question 2
Left hand side of d.e. isd
dxy =
d
dx(2x+ c)
= 2 +d
dxc
= 2
= Right hand side of d.e.
Which verifies that the function is a solution of the di!erential equation.
Question 3
Left hand side of d.e. isd
dxy =
d
dx
#5
7x7 % 16
4x4
$
= 5x6 % 16x3
= Right hand side of d.e.
Which verifies that the function is a solution of the di!erential equation.
Question 4
Left hand side of d.e. isd
dxy =
d
dx
#!x3
3+ c
$
= !x2 +d
dxc
= !x2
= Right hand side of d.e.
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Which verifies that the function is a solution of the di!erential equation.
Question 5
Left hand side of d.e. isd
dxy =
d
dx(sin(x) + 3)
= +cos(x)
= Right hand side of d.e.
Which verifies that the function is a solution of the di!erential equation.
Question 6
Left hand side of d.e. isd
dxy =
d
dx
#1
5e5x
$
= e5x
= Right hand side of d.e.
Which verifies that the function is a solution of the di!erential equation.
Question 7
Left hand side of d.e. isd
dxy =
d
dx
#x2
2+ sin(x)
$
= x+ cos(x)
= Right hand side of d.e.
Which verifies that the function is a solution of the di!erential equation.
Question 8
Left hand side of d.e. isd
dxy =
d
dx
#1
3sin(3x)
$
=1
3# cos(3x)# 3
= cos(3x)
= Right hand side of d.e.
Which verifies that the function is a solution of the di!erential equation.
Question 9
Left hand side of d.e. isd
dxy =
d
dx
)sin(x2)% !
*
= cos(x2)# 2x+d
dx!
= cos(x2)# 2x
= Right hand side of d.e.
Which verifies that the function is a solution of the di!erential equation.
Question 10
Left hand side of d.e. isd
dxy =
d
dx
'ex
2
+ c(
= ex2 # 2x+
d
dxc
= ex2 # 2x
= Right hand side of d.e.
Which verifies that the function is a solution of the di!erential equation.
Question 11
Left hand side of d.e. isd
dxy =
d
dx
)x5 cos(15x4)
*
= 5x4 cos(15x4)% x5 sin(15x4)# 15# 4x3
= 5x4 cos(15x4)% 60x8 sin(15x4)
= Right hand side of d.e.
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Which verifies that the function is a solution of the di!erential equation.
5.13 Answers to Exercises 3.3.1
Question 1 y(x) =3
4x4 + c.
Question 2 y(x) = 2x+ c.
Question 3 y(x) =5
7x7 % 4x4 + c.
Question 4 y(x) =!
3x3 + c.
Question 5 y(x) = sin(x) + c.
Question 6 y(x) =1
5e5x + c.
Question 7 y(x) = x2 + sin(x) + c.
Question 8 y(x) =1
3sin(3x) + c.
Question 9 y(x) = sin(x2) + c.
Question 10 y(x) = ex2
+ c.
Question 11 y(x) = 5 ln(x)% cos(3x5) + c.
5.14 Answers to Exercises 3.6.2
Question 1 y(x) = ex, y(x) = 5ex, y(x) = %153!ex, as examples. There are many more.
Question 2 Can you think of a function X, which is a function of t, such that when you di!erentiate thatfunction you get the same function you first thought of.
Question 3 X(t) = et, X(t) = 5et, X(t) = %153!et, as examples.
Question 4 X(t) = Aet, for A constant.
Question 6 Particular solutions Z(y) = ey, Z(y) = %21ey, Z(y) = %(21e!"e + sin(e2) % 15!3e"4)ey; generalsolution Z(y) = Aey.
5.15 Answers to Exercises 3.6.4
Question 1 (b), (c), (d).
Question 2 (c), (d).
Question 3 (a) (iv), (b) (v), (c) (vi), (d) (iii), (e) (i), (f) (ii).
Question 4 (a) (v), (b) (ii), (c) (iii), (d) (i), (e) (vi), (f) (iv).
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5.16 Answers to Exercises 4.1.1
Question 1
(a) When t = 0 H = 15.
(b) When t = 1 H = 13.5.
(c) When t = 0 H = 24.
(d) When t = 48 H = 12.7.
(e) When t = 0 H = 1.55.
(f) When t = 72 H = 2.44.
(g) When t = 24 H = 7.
(h) When t = 0 H = 15.3.
Question 2
(a) When t = 0 M = 150.
(b) When t = 150 M = 45.
(c) When t = 0 M = 250.
(d) When t = 2880 M = 17.
(e) WhendM
dt= 12 M = 175.
(f) When t = 300 M !(t) = 2.
(g) When t = 60 M !(t) = 12.5.
(h) When t = 0 M = 15.3.
(i) When t = 60 M ! = 3.
(j) When t = 360dM
dt= 3.5.
(k) When t = 60 H = 145.
Question 3
(a) When t = 0 P = 2.34.
(b) When t = 3.5 P = 1.324.
(c) When t = 0 P !(t) = 2.
(d) When t = 48 P ! = %0.524.
(e) R = 0.5.
(f) When t = 582 P = 0.
(g) When t = 24 P = 22.564.
(h) When t = 24 P = 1000. Note if P is given as 1000 this must already be in units of 1000s. For P = 1000there are 1000, 000 fish!
(i) When t = 0dP
dt= 2.0.
(j) When t = 24 P ! = 2.0.
(k) When t = 150 P = 0. Or this is saying after 150 hours there are no fish left.